aaaiteiS'Siij" 
 
 OR. 
 
 mis 
 
 ij^i-^-? W^.H"? *'^'''^**y ;'' >\**'#j' '-^ o ':'-^ 
 
CORNELL 
 
 UNIVERSITY 
 
 LIBRARY 
 
 L= 
 
Cornell University Library 
 
 a»-w "101475 
 
 Manual of assaying gold, silver, copper 
 
 3 1924 031 250 750 
 olln,anx 
 
B Cornell University 
 y Library 
 
 The original of this book is in 
 the Cornell University Library. 
 
 There are no known copyright restrictions in 
 the United States on the use of the text. 
 
 http://www.archive.org/details/cu31 924031 250750 
 
ASSAYING 
 
 OF 
 
 GOLD, SILVER, COPPER AND LEAD 
 
 ORES. 
 
MANUAL OF ASSAYING 
 
 GOLD, SILVER, COPPER 
 
 LEAD ORES. 
 
 By WALTER LEE BROWN, B.Sc. 
 
 WITH ILLUSTRATIONS. 
 
 CHICAGO: 
 
 JANSEN, McCLURG & COMPANY. 
 i88^. 
 
/i 
 
 •9^^f 
 
 ^cornell\ 
 university 
 
 LIBRARY/; 
 
 Copyright 
 
 By JANSEN, McCLURG & CO. 
 
 A.D. 1883. 
 
 
PREFACE. 
 
 When I entered upon the task of preparing this 
 book, it was with the idea of furnishing a guide to 
 those, who, having had no previous technical or es- 
 pecially scientific education, desired to learn some- 
 thing of the practical assaying of gold and silver ores, 
 and in whose hands I could place no work that could 
 give them this information in a clear, simple and 'thor- 
 oughly detailed manner, and unburdened with un- 
 necessary matter. 
 
 This intention I have tried to adhere to all the way 
 through, and while I have added other information 
 which was pertinent, I have kept such increase in an 
 appendix, so that the body proper of the work con- 
 tains the real subject matter. 
 
 It is my sincere belief that there is no book in the 
 English language on the subject of assaying which 
 occupies the space that this little manual tries to fill. 
 
 A number of such publications fail to meet the 
 want, on account of their antiquity, they having been 
 written some thirty years back ; hence their methods, 
 apparatus, etc., are not suited to the assayers of to- 
 day. Others are either more suitable as books of 
 reference, or do not give sufficient detail for the inex- 
 perienced. 
 
 It is this latter fault I have carefully endeavored 
 to avoid, and perhaps have gone to the other extreme. 
 At all events, I have tried to give here in print the 
 
 5 
 
PREFACE. 
 
 precise instruction which I have previously imparted 
 orally to my students. Those who may choose to 
 criticise, will remember for whom this hand-book is 
 written. 
 
 While I have consulted many of the authorities 
 listed on pp. 268-74, it is from three in particular that I 
 have drawn great help. I refer to Mitchell's Manual 
 of Practical Assaying, Ricketts' Notes on Assaying, 
 and Kustel's Roasting of Gold and Silver Ores. 
 
 Besides the above, and other printed sources referred 
 to in their proper places, I wish to publicly thank 
 the following gentlemen who have very kindly aided 
 me in my work with valuable information: Mr. S. A. 
 Reed, Irwin, Colo.; Mr. A. H. Low, Assayer of the 
 Boston and Colorado Smelting Works, Argo, Colo.; 
 Mr. C. Boyer, Assayer of the U. S. Branch Mint, Den- 
 ver, Colo.; Mr. M. G. Nixon, Engineer, and Mr. R. G. 
 Coates, both of Chicago. 
 
 In conclusion I trust that all those who are willing 
 to aid me in the preparation of an improved edition 
 of this book, will at once communicate with me. 
 
 Walter Lee Brown, 
 Analytical and Consulting Chemist and Assayer, 
 105 Metropolitan Block, Chicago, 111. 
 March, 1883. 
 
CONTENTS. 
 
 PART I. 
 
 APPARATUS AND RE-AGENTS. 
 
 CHAPTER I. 
 
 APPARATUS USED IN ASSAYING. 
 
 Implements for Pulverizing, Sampling, etc., i8 
 
 Scales and Balances, 28 
 
 Weights, . 3g 
 
 Furnaces, . .42 
 
 Furnace Tools, . . jg 
 
 Appaijatus Used in the Furnace, . 68 
 
 Apparatus of Glass and Porcelain, . - 77 
 
 Miscellaneous Apparatus, - .... 81 
 
 CHAPTER II. 
 RE-AGENTS USED IN ASSAYING. 
 
 Dry Re-agents for Assaying, . 93 
 
 Wet Re-agents for Assaying, 106 
 
 Re-agents for Analysis, . . 108 
 
 CHAPTER III. 
 
 TESTING OF RE-AGENTS ; PRELIMINARY WORK. 
 
 I. Testing of Litharge for Silver, . . 116 
 
 II. Testing of Granulated Lead for Silver, ' 118 
 
 III. Testing of Sheet Lead for Silver, . . 120 
 
 IV. Determination of the Reducing Powers of Re- 
 
 ducing Agents, . 121 
 
 V. Determination of the Oxidizing Power of Nitre 
 
 (Nitrate of Potash), ... . 122 
 
 VI. Determination of the Reducing Powers of Cer- 
 tain Ores, .... . 123 
 7 
 
CONTENTS. 
 
 PART II. 
 
 ASSAYING. 
 
 CHAPTER I. 
 
 GOLD AND SILVER ORES. 
 Occurrence, . . 129 
 
 Assay, . . . . 132 
 
 L Preparation of the Sample, . 133 
 
 IL Scorification Process, 139 
 
 a. Preparation of Charge, 141; b. Scorification, 
 146 ; c. Cupellation, 152 ; d. Weigliing the 
 Gold and. Silver Bead, 160 ; <r. Parting, 161 ; 
 /. Inquartation, 164 ; g. Weighing the Gold 
 Residue, 165 ; //. Calculations, 166. 
 in. Crucible Process, 170 
 
 CHAPTER II. 
 
 COPPER ORES. 
 
 Occurrence, 180 
 
 Assay, . ... 181 
 
 I. Method for Native Copper, 182 
 
 II. Method for Oxides and Carbonates of Copper, 
 
 Free from Sulphur, . . 182 
 
 III. Method for Sulphides of Copper, vj^ith Ar- 
 senic, Antimony, etc., 183 
 
 CHAPTER III. 
 
 LEAD ORES. 
 
 Occurrence, . _ _ 185 
 
 Assay, . . . . 186 
 
 I. Methods for Galena, 186 
 
 II. Methods for Oxides and Carbonates, 194 
 
APPENDIX. 
 
 203 
 
 239 
 
 243 
 
 SECTION I. 
 
 Special Methods. 
 
 I. Assaying of the Various Minerals Contained 
 
 IN an Ore, 
 II. Assaying of Ores Containing Free Gold or Free 
 Silver, . . . 
 
 III. Analysis of Copper Ores, . . 210 
 
 IV. Amalgamation Assay or Laboratory Mill Run, 221 
 V. Pan Test for Gold ("Panning"), - 225 
 
 VI. Chlorination Assay of Gold Ores, 234 
 
 VII. Chlorination Test for Silver, . . 237 
 
 VIII. The Assay of Gold Bullion. . 
 IX. The Assay of Base Bullion, 
 X. Color Tests; Scorification, Scorifier, Cupel, 246 
 
 XI. Qualitative Tests; Carbonates, Chlorides, Sul- 
 phates, Sulphides, Tellurides, Copper, Iron, 
 Lead, Silver, . 249 
 
 XII. Brief Scheme for Silica, Iron and Manganese, 254 
 XIII. Determination of Moisture in an Ore, 255 
 
 SECTION II. 
 
 Lists and References. 
 
 List of the Principal Gold Minerals Found in the 
 
 United States, 257 
 
 Minerals Likely to Carry Gold, . 258 
 
 List of the Principal Silver Minerals Found in the 
 
 United States, . 258 
 
 Minerals Likely to Carry Silver, 261 
 
 List of the Principal Copper Minerals Found in the 
 United States, ,. . 262 
 
 9 
 
lO APPENDIX. 
 
 List of the Principal Lead Minerals found in thf. 
 United States, 265 
 
 List of Useful Books on Subjects More or Less Con- 
 nected WITH Assaying : General Science ; General 
 Chemistry; Chemical Technology; Reference Books 
 on Chemistry; Text-Books on Theoretical Chemis- 
 try; General Qualitative Analysis; General Quan- 
 titative Analysis; Special Quantitative Analysis; 
 Volumetric Analysis ; Laboratory Manipulation; 
 Geology ; Mineralogy ; Blow-pipe Analysis ; Metal- 
 lurgy AND Mining; Assaying; Metric System 
 
 Weights and Measures ; Mining Law, 268 
 
 Form for Certificate of Assay, . . 275 
 
 Outfit, 
 
 Index, . 
 
 276 
 
 SECTION III. 
 
 Tables. 
 
 Multiplication Table for Gold and Silver, 279 
 
 Table of Values of Gold and Silver, . . 280 
 
 Tables of Weights; Avoirdupois; Troy; Apothecaries'; 
 
 French or Metric System, . . 281 
 
 Equivalents of Some of the English and French 
 
 Weights, - . . . . 28'; 
 
 Assay Ton Equivalents in Grammes, Troy Grains and 
 
 Troy Ounces, . _ 286 
 
 297 
 
INTRODUCTION. 
 
 In our present state of knowledge we be- 
 lieve all matter to be composed of one or 
 more elements or original simple substances. 
 
 These elements are considered to be sixty- 
 five in number. Certain of them have what 
 we may call a commercial im,portaitce. (See 
 Introduction to Attwood's Blow-pipe Assay- 
 ing.) They are as follows, the metals being 
 in italics: 
 
 1. Aluminium. 
 
 2. Antimony. 
 
 3. Arsenic. 
 
 4. Barium. 
 
 5. Bismuth. 
 
 6. Boron. 
 
 7. Bromine. 
 
 8. Cadmium. 
 
 9. Calcium. 
 
 10. Carbon. 
 
 11. Chlorine. 
 
 12. Chromium. 
 
 13. Cobalt. 
 
 14. Copper. 
 
 15. Fluorine. 
 
 16. Gold. 
 
 17. Hydrogen. 
 
 18. Iodine. 
 
 19. Iridium. 
 
 20. Iron. 
 
 21. lead. 
 
 22. Lithium. 
 
 23. Magnesium. 
 
 24. Manganese. 
 
 25. Mercury. 
 
 26. Molybdenum. 
 
 27. Nickel. 
 
 28. Nitrogen. 
 
 29. Oxygen. 
 
 30. Palladium. 
 
12 
 
 IN TROD UCTION. 
 
 39 
 
 Tin. 
 
 40 
 
 Titanium. 
 
 41 
 
 Tungsten. 
 
 42 
 
 Uranium. 
 
 43 
 
 Vanadium. 
 
 44 
 
 Zinc. 
 
 45 
 
 Zirconium 
 
 31. Phosphorus. 
 
 32. Platinum. 
 
 33. Potassium. 
 
 34. Silicon. 
 
 35. Silver. 
 
 36. Sodium. 
 
 37. Strontium. 
 
 38. Sulphur. 
 
 Some of the above are valuable in them- 
 selves, others in combination. 
 
 The remainder of the elements, which have 
 no especial value excepting perhaps as curi- 
 osities, are : 
 
 1. Caesium. 
 
 2. Cerium. 
 
 3. Columbium. 
 
 4. Daiiyum. 
 
 5. Didymium 
 
 6. Erbium. 
 
 7. Gallium. 
 
 8. Glucinum. 
 
 9. Indium. 
 
 10. Lanthanum. 
 
 11. Osmium. 
 
 12. Rhodium. 
 
 13. Rubidium. 
 
 14. Ruthenium. 
 
 15. Selenium. 
 
 16. Tantalum. 
 
 17. Tellurium. 
 
 18. Thallium. 
 
 19. Thorium. 
 
 20. Yttrium. 
 
 Besides the sixty-five elements above enu- 
 merated, there are some eight or ten ex- 
 tremely rare metals (decipium, holmium, 
 mosandrium, norwegium, philippium, sama- 
 rium, scandium, terbium, thulium, ytterbium. 
 
INTRODUCTION. 13 
 
 etc.), whose existence is not yet quite satis- 
 factorily proven. 
 
 In order to ascertain the value of an orfe, it 
 is necessary to determine the percentage of 
 the metal or metals which it contains. 
 
 This is the first thing to be done — an after 
 consideration is the question of the presence 
 of other ingredients which may injuriously 
 affect the value of the ore or product. 
 
 There are two general methods, known 
 respectively as assaying ■AXidi analysis, whereby 
 we may test an ore to learn its composition. 
 
 A comprehensive definition of assaying is 
 to call it that branch of exact science which 
 enables us to find out of what a substance is 
 composed and the proportions, by means of 
 dry re-agents and heat. 
 
 On the other hand, analysis is that branch 
 which effects the same results mainly by the 
 use of wet re-agents, with or without the aid 
 of heat. 
 
 In spite of this distinction, wet assays, as 
 opposed to dry or fire assays, are continually 
 spoken of ; still, to be as consistent as possi- 
 ble, the terms assaying and analysis, as defined 
 above, will be used throughout this work. 
 
14 INTRODUCTION. 
 
 The greater number of the processes given 
 in this little book come under the former 
 heading, while analysis proper is employed 
 in only a few cases. 
 
 The following metals are sought for in ores 
 by assaying : antimony, bismuth, cobalt, cop- 
 per, gold, iron, lead, nickel, platinum, silver, 
 tin and zinc. 
 
 It is the object of this manual to treat only 
 of gold, silver, copper and lead. For informa- 
 tion concerning the assaying of the remaining 
 metals just mentioned, the student must seek 
 it on page 273, among the various works on 
 assaying there quoted. 
 
PART I. 
 APPARATUS AND RE-AGENTS. 
 
MANUAL OF ASSAYING. 
 
 PART I. 
 
 APPARATUS AND RE-AGENTS. 
 
 CHAPTER I. 
 APPARATUS USED IN ASSAYING. 
 
 It is as true of the art of assaying as of 
 any other, that "good work requires good 
 tools." While many of the latter can be 
 dispensed with by the skilled assayer, it- is 
 often convenient, if not absolutely necessary, 
 for the unskilled to have the best utensils for 
 the work required. 
 
 I shall therefore give an exhaustive list of 
 apparatus needed for the processes herein 
 described, but shall try to avoid mentioning 
 many implements which are not essential. 
 
1 8 MANUAL OF ASSAYING. 
 
 IMPLEMENTS FOR PULVERIZING, SAMPLING, ETC. 
 
 Iron Mortars and Pestles. — Two sizes of 
 mortars are handy, a large one 1 1 inches in 
 diameter, and weighing with pestle about 35 
 pounds (2 gallons capacity), and a smaller 
 one of 5 inches diameter and 7 pounds weight 
 (^ gallon capacity). Instead of both, a 
 medium size, 8 inches diameter, in 
 weight about 19 pounds (i gallon 
 capacity), may be employed. They 
 may be either bell or urn-shaped. 
 fiG. I. Care should be taken to remove 
 
 all ore from the mortars after grinding. Gen- 
 erally an old towel, rag, or even paper, will 
 suffice to do this, but occasionally washing 
 must be resorted to. Dry thoroughly after 
 the latter operation. Triturating with dry 
 sand often answers the purpose. When not 
 in use let the mortars rest mouth downward. 
 Crushers.— 11\\&?,& are intended to take the 
 place of the mortar and pestle for crushing 
 comparatively large quantities of ores. For 
 small samples the mortar will do very well, 
 
APPARA TUS USED IN ASSA YING. 
 
 19 
 
 but for say 20 pounds and upward, some sort 
 of a crusher will be a desideratum. Espe- 
 cially will it be needed in a large assay labo- 
 ratory. 
 
 There are quite a number of hand crushers 
 in the market intended solely for laboratory 
 purposes, such as the Alden, Blake, Forster, 
 Lipsey, etc. 
 
 Fig. 2. 
 
 Among the best is the Lipsey, which is 
 represented in full in fig. 2, and in section in 
 
20 
 
 MANUAL OF ASSA YING, 
 
 Fig. 3- 
 
 fig. 3. It can be turned either by hand or 
 power. 
 
 The value of whatever crusher is employed 
 will depend mainly upon the ease, rapidity 
 and thoroughness with which it can be cleaned. 
 
 Certain special apparatus, as hand-stamps 
 and pulverizers, must be left to the neccessi- 
 ties and preferences of the individual assayer. 
 
APPARA TUS USED IN ASSA YING. 
 
 21 
 
 Pulverizing Plate and Rubbers. — These are 
 so useful and convenient that they can hardly 
 
 Fig. 4. 
 
 be dispensed with ; in fact, if much assaying 
 is to be done, they will become absolutely 
 necessary. They are represented in fig. 4. 
 The iron plate, which should be perfectly 
 true and have a smooth surface, is made of 
 varying dimensions, as 12x12, 18x24, 23x24, 
 24x24, 24x30 and 24x36, in inches. It is 
 made with no protecting rims, or with rims at 
 the sides only (as figured), or with a rim at 
 each side and at one end, leaving one end open. 
 In some cases the side rims gradually shallow 
 
22 MANUAL OF ASSA YING. 
 
 from the back to the front. The size I use, 
 and with which I have no fault to find, is 
 18x24 inches (inside measurement); thickness 
 of bottom, I inch ; rims, f inch wide and \\ 
 inches high ; weight, 150 pounds, 
 
 (The only improvement I can suggest would 
 be to have the back corners rounded instead 
 of being right angles, in order to facilitate 
 the- removal of pieces *of ore and the dust. 
 Or the rims might be cast at an angle of say 
 30° instead of being perpendicular to the 
 surface.) 
 
 The rubber, rocker, pulverizer; grinder, 
 muller, bucking-hammer (by which various 
 names it is known), to go with above plate, 
 is 8 inches long and 4 wide ; thickness at 
 ends, \\ inches; in centre, 2\; surface true 
 and smooth ;' weight about 14 pounds. Other 
 rockers made are, in general dimensions, 4x5, 
 4X5i. 4x6, 6x7 and 8x10 inches. 
 
 An axe-handle is fitted into the socket on 
 top of rocker, and then it is ready for use. 
 
 The operation of grinding, or rubbing, or 
 
APPARATUS USED IN ASSAYING. 23 
 
 pulverizing, is managed as follows: The ore, 
 previously broken into fine pieces as directed, 
 is placed upon the clean surface of the plate, 
 the rocker is now laid upon it, and, with one 
 hand firmly pressed upon the body of the 
 rocker, and the other grasping its handle, it is 
 moved backward and forward with an oscil- 
 lating motion. This knack of grinding, al- 
 though not easy to describe, is soon acquired. 
 
 When a very hard ore is to be pulverized, 
 it can much more quickly be finished with an 
 8x10 rocker, weight 60 pounds. The addi- 
 tional weight and greater width have a marked 
 effect. An intermediate size of about 30 
 pounds weight would not be amiss. 
 
 Clean the plate and rockers after use with 
 old rags or by grinding sand as in the case of 
 the mortars. 
 
 A substantial table or frame work will be 
 wanted upon which the plate is to be set at 
 the proper height for working, and parallel 
 with the floor. 
 
 In Mr. S. A. Reed's laboratory the plate is 
 
24 MANUAL OF ASSAYING. 
 
 set at an angle inclining toward the operator 
 so as to allow of more effective pressure at 
 the bottom, and slipped under the front end 
 of the plate is a trough or gutter of sheet-tin 
 or zinc, as shown in the figure. Its object is 
 to catch any particles that may roll down the 
 plate, and after the sample has been pulver- 
 ized, the whole of the powder is brushed down 
 into it. The trough is easily detached from 
 the plate and its contents can then be brushed 
 into a sieve. This sirhple device may replace 
 one of the zinc sifting pans spoken of else- 
 where. 
 
 Sample Shovels. — A pitch-fork with each tine 
 transformed into a narrow trough would give 
 a fair idea of the appearance of one of these 
 shovels. A better form consists of two troughs 
 from four to six inches deep united, with a 
 space between, and provided with a long han- 
 dle. These implements are more needed in 
 sampling works proper than in the ordinary 
 laboratory. 
 
 Samplers (also known as dividers). — One 
 
APPARA TUS USED IN ASSA YING. 25 
 
 form of these is shown in fig. 5, 
 
 ^ "~^~j and consists of a frame with 
 
 -^r partitions running lengthwise 
 
 Fig. 5. 1 !• 1 
 
 at equal distances apart, and 
 having each alternate space covered at the 
 bottom. It is made of tin or copper, and it 
 is well to have three sizes. A second pattern 
 
 is represented in 
 
 fig. 6. The first 
 
 form, however, is 
 
 preferred, as being 
 
 Fig. 6. more durable. 
 
 To use either, sprinkle over and across the 
 
 broken ore to be sampled, and retain that 
 
 which catches in the troughs, 
 
 A pulp is sometimes sampled by the use of 
 a sampler of tin, having troughs -^ jnch in dia- 
 meter and j^ inch apart. To use, sprinkle the 
 sample across, over a piece of clean paper, 
 and separate that which goes between the 
 troughs from that which catches in them. Af- 
 ter putting aside the latter portion, sprinkle 
 across the sampler the former portion, and so 
 
26 MANUAL OF ASSAYING. 
 
 continue until a quantity is obtained about 
 sufficient for assay. 
 
 Sieves. — A sieve of 80, 90 or 100 meshes to 
 the linear inch is necessary. Such sieves are 
 furnished of 5, 6, 7, 8, 9, 10, 12 and 15 inches 
 diameter (6 to 8 inches is a good size), of 
 copper or brass wire in a wooden frame. 
 Those composed of horse hair are apt to 
 deteriorate. The box-sieve of tinned iron, 
 consisting of a sieve (of 80 to 100 mesh) 
 with tightly fitting bottom to catch all the 
 sifted material, and cover to retain the dust, 
 is a valuable implement. 
 
 A 40-mesh sieve is useful for sieving cer- 
 tain chemicals, and two common flour sieves 
 are wanted for bone-ash and granulated lead. 
 
 Zmc Sifting Pans. Fig. 7. — These will be 
 
 Fig. 7. 
 
 found convenient, and are better than paper 
 
APPARATUS USED IN ASSAYING. 2 J 
 
 for sifting over. A pair is necessary, the 
 material sheet zinc. Length in full 31 inches, 
 of body 25 inches, of neck 6 inches, width of 
 body 12 inches, of neck 2 inches, height of 
 rim 2|- inches, with upper edge turned over 
 heavy iron wire. 
 
 Spatulas and Spoons. — By a spatula we 
 
 Fig. 8. 
 
 mean an instrument shaped somewhat like a 
 table-knife (fig. 8), and used for mixing 
 paints, ores, charges, etc. It may be of iron, 
 steel, copper, platinum, silver, ivory, horn, 
 porcelain or glass. A large one of steel 
 or iron (such as painters use), length in full 
 io|- inches, blade 5^^ inches long by i^ 
 wide, is a very good size for mixing ores 
 and crucible charges. For weighing out ores 
 and mixing scorification charges, a smaller 
 one of steel, length 6 inches, blade 3x^ inch 
 is useful. 
 
28 MANUAL OF ASSAYING. 
 
 Two or three horn spoons, with or without 
 handles, are serviceable for various purposes. 
 
 SCALES AND BALANCES. 
 
 Two balances will be sufficient for the 
 ordinary work of the assayer; a small one 
 for weighing fluxes, ores, lead buttons, cupels, 
 etc., and a more delicate one for very accu- 
 rately weighing the gold and silver beads 
 and gold residues. 
 
 Scales for Pulps and Fluxes. — Considera- 
 ble latitude can be allowed in the choice of 
 such scales. Balances can be procured carry- 
 ing 2, 5, lo, 20 or 30 ounces and upward; and 
 ranging in delicacy from -^-^ of a grain to i 
 grain. For descriptions, illustrations, and 
 prices of these and others, see the lists of 
 the various manufacturers. 
 
 Not wishing to puzzle the student too 
 much, I specify but four : 
 
 Fig. 9 represents as satisfactory a pair as 
 can be wanted. It has a spirit level and two 
 thumb-screws, movable scale-pans (3^ inch 
 
APPARA TUS USED IN ASSA YING. 
 
 29 
 
 Fig. 9. 
 
 diameter), and when it is to be transported, 
 all the parts on the box can be packed in the 
 drawer. Its capacity is 10 oz. (about 311 
 grammes), and it is sensible to -^ of a grain 
 (about i\ milligrammes). Its cost is $22.00. 
 (See Becker's list, No. 19.) A glass case in 
 which to keep the scales is a good thing to 
 have, and costs $6.00. 
 
 Troemner makes a similar balance, capaci- 
 
so 
 
 MANUAL OF ASSA YING. 
 
 ty 1 6 oz., sensibility -^ grain, diameter of 
 pans 4 inches, price $18.00. (See Troem- 
 ner's list, analytical scale No. 2, fig. 22.) 
 
 A still cheaper ' but satisfactory balance, 
 similar to the preceding, is likewise furnished 
 by Troemner, capacity 8 oz., sensibility -^ 
 
 Fig. io. 
 
 grain, diameter of pans 3^ inches, price 
 $15.00. It is represented in fig. 10. The 
 objections to it are that it lacks the spirit 
 level and adjusting screws, so that it is not 
 always easy to get it into perfect equilibrium. 
 
 No advice need be given for setting up the 
 above, as printed directions usually accom- 
 pany the scales. 
 
 Whatever pair be used, it^ is advisable to 
 
APPARA TUS USED IN ASSA YING. 
 
 31 
 
 take two large watch glasses, in diameter a 
 trifle less than that of the scale pans, and file 
 down one or the other till they balance each 
 other perfectly. Weigh all charges in these, 
 thus avoiding any. danger of corrosion or at- 
 trition of the scale pans. 
 
 A soft brush should be employed to brush 
 out the contents of the glasses. 
 
 It is a good plan to always place the weights 
 in one pan (the right-hand one), and whatever 
 is to be weighed always in the other. 
 
 In case many crucible assays are to be made 
 (requiring the weighing of many fluxes), a 
 great deal of wear and tear of the balances 
 described can be avoided by substituting 
 
 hand-scales, which are 
 
 Fig. II. 
 
 cheap and serviceable. 
 They are made with 
 brass beam, from which 
 horn scale-pans are 
 suspended by means 
 of silk threads (fig. 
 11).' They can be se- 
 
32 MANUAL OF ASSAYING. 
 
 lected from a dozen sizes, the length of beam 
 ranging between 4 and 12 inches {j\ or 8|- is 
 best — prices $2.75 and $3.00). Support them 
 on a nail by the ring at the top, and use them 
 for any and all weighings save those of the 
 ores. Of course no watch-glasses need be 
 used with these scales. Their sensibility is 
 from -^ to ^V grain. 
 
 Occasionally it becomes necessary to weigh 
 large quantities (pounds) of ores, fluxes, etc. 
 Use whatever scales are easiest obtained; I 
 need not go into detail concerning them. 
 
 Balances for Weighing Gold and Silver Beads. 
 — Here likewise is a range of choice, and per- 
 sonal preference comes largely into play. 
 
 When the assayer intends to travel consid- 
 erably, the balance now spoken of will be the 
 most suitable. Length 9 to 9^ inches, height 
 9f inches, width from 3 to 4 inches. It packs 
 into a light box, and by means of a strong 
 leathern strap can be carried by the hand. 
 Total weight, boxed, about 4^^ pounds. With 
 the proper weights this balance will weigh 
 
APPARATUS USED IN ASSAYING. 
 
 33 
 
 •Jj- milligramme, and by use of the swinging 
 needle and ivory scale will indicate -^ milli- 
 gramme. 
 
 It is made both by Becker (No. 2 of his 
 list) and Troemner — the prices, with weights 
 (i gramme down to ^ milligramme), being 
 $75 and $65 respectively. 
 
 Fig. 12. 
 
 When the balance is not liable to be moved 
 around very often, that shown in fig. 12 will 
 serve nicely, and is considerably cheaper. The 
 needle indicates |- of a milligramme, and each 
 pan can bear a load of 2.5 grammes. Price 
 
34 
 
 MANUAL OF ASSAYING. 
 
 $55.00 of either Becker (No. i) or Troemner 
 (No. i). 
 
 A similar but larger and somewhat more 
 delicate balance is made by Becker (No. 3 — 
 price $78.00). The needle indicates 10 divis- 
 ions on the scale for i milligramme. The 
 greatest objection to all of the preceding bal- 
 ances lies in the fact th^t they have no grad- 
 uated beam to carry a riaer to show the weight 
 below 10 milligrammes, but instead indicate it 
 by the deviation of a needle. The following 
 possess this advantage: 
 
 
 Fig. 13. 
 
 Troemner's No. 2 (fig. 13 of this book) is a 
 fine balance. The beam at the right is divided 
 
APPARATUS USED IN. ASSAYING. 35 
 
 into tenths, each tenth numbered and corres- 
 ponding to I milligramme, and furthermore 
 each tenth is subdivided into tenths, so that 
 by rneans of the movable rider carried by the 
 rod (seen in the upper right portion of the 
 engraving), a button of -^ milligramme can 
 easily be weighed. And more; since the spaces 
 between the -^ milligramme divisions are ap- 
 preciable, by placing the rider half-way be- 
 tween any two, a weight of -^ of a milli- 
 gramme can be determined. Price of this 
 balance, $80.00. 
 
 There is a still larger balance (Becker No. 
 5, Troemner No. 3 — price $95.00) which is 
 more delicate and better finished than the 
 preceding. 
 
 Oertling, of London, furnishes a most ex- 
 quisitely dehcate and accurate balance (No. 
 12), represented in fig. 14, which is far ahead 
 of any other- made. It is expensive ($200), 
 but where very delicate work is required, as 
 in weighing the gold residues from small 
 quantities of low grade ores, it is indispensable. 
 
36 
 
 MANUAL OF ASSAYING. 
 
 Fig. 14. 
 
 See the price-lists of the manufacturers 
 quoted. 
 
APPARA TUS USED IN ASS A YING. 
 
 37 
 
 Special Directions. — It is beyond the pro- 
 vince of this book to enter into a study of the 
 philosophy of the balance, and neither do I 
 consider it necessary to give minute and ex- 
 act details of its various parts. For these 
 consult the larger manuals. (Mitchell, pp. 
 
 25-30.) 
 
 Nor need I give many directions as to the 
 proper setting up of such balances. Printed 
 directions usually accompany them, as in the 
 case of the less delicate scales. 
 
 It must be remembered that all of the bal- 
 ances described are very delicate pieces of 
 apparatus, and should be guarded with the 
 utmost care. They should be placed far from 
 the heat of the furnace and even away from 
 the rays of the sun, tending to unequal ex- 
 pansion and subsequent contraction. Shocks 
 must be avoided and even continual gentle 
 agitation, and they should be kept away from 
 acid fumes (particularly those of nitric acid\ 
 and out 'of moist atmospheres. By having a 
 small vessel filled with dry fused calcic chloride 
 
38 MANUAL OF ASSA YING. 
 
 always inside the case of the balance, the 
 moisture present will be absorbed by it, and 
 thus prevent, in a measure, the rusting of the 
 steel parts of the balance. When saturated 
 replenish. 
 
 These balances are provided with steel 
 knives and agate bearings, spirit level and 
 set-screws. By means of the latter and by 
 observing the spirit level, the balance can be 
 placed in a state of perfect equilibrium, and 
 it should always be kept in such. To ascer- 
 tain whether it is in adjustment, throw the 
 rest down, thus leaving the pans free, and 
 vibrate the needle by a puff of wind from 
 the hand. The needle should go to the same 
 distance on either side, less a very small frac- 
 tion due to the decreasing momentum. If it 
 does, the balance is in equilibrium; if it does 
 not, adjust the difference by means of a little 
 screw at one end or' the other of the beam, 
 or arrow in the centre. 
 
 When not in use, the rest should not be 
 left down, and on the other hand, when using 
 
APPARA TUS USED IN ASSA YING. 
 
 39 
 
 the balance, it should not be brought up when 
 the needle is vibrating, as this tends to throw 
 the knives off the agate bearings, and so 
 work injury. 
 
 With these balances, as with the ore scales, 
 put the weights always in one pan, the mate- 
 rial to be weighed in the other. Since the 
 rider in most balances is used on the bearn 
 at the right, it is better to employ the right- 
 hand scale-pan for the weights. Do not 
 leave the weights on the pan for too long a 
 time. 
 
 A very soft and fine camel's hair brush 
 may be employed to cleanse the scale-pans 
 or other parts from dust. 
 
 Finally never use these balances for any 
 other purposes than for weighing gold and 
 silver beads, small pieces of silver or gold, 
 etc. 
 
 WEIGHTS. 
 
 The assayer needs three sets: 
 1st. A set in the French or metric system, 
 ranging from 50 grammes down to i centi- 
 
40 MANUAL OF ASSAYING. 
 
 gramme (lo milligrammes). Since they are 
 not to be used for very accurate work, but 
 only for weighing fluxes, lead buttons, and 
 other comparatively rough purposes, they 
 need not be very expensive ( $5.00 to 
 $6.00). 
 
 2d. A second set of metric weights, to be 
 very accurate, their range from i gramme to 
 yijj- milligramme, their use for weighing gold 
 and silver beads. Such a set is included in 
 the price given for the assay balance for gold 
 iJ^^^g^M^pJ" dnd silver beads first men- 
 
 tj^'^a^^ay-^ tioned. Separately, they 
 - "^ ~""^^ "^^^1 c°^* $8.00 to $10.00. 
 p.,(j jj^ Fig. 15 represents a box of 
 
 these weights. 
 
 3d. A set of assay ton weights. These 
 are important, and should be very accurate. 
 Their range is from ^ to 4 A. T., and price 
 about $6.00. 
 
 These, weights are simply invaluable on 
 account of their use requiring no calculations 
 beyond a few multiplications or divisions. 
 
APPARATUS USED IN ASSAYING. 4 1 
 
 Their connection with ounces, pounds and 
 tons is seen very easily. 
 
 There are 29,166 Troy ounces in a ton of 
 2,000 lbs. There are 29,166 milligrammes in 
 I assay ton, therefore i milligramme corre- 
 sponds to I. ounce. Consequently, if on an 
 assay of ^ A. T., a bead of 6 milligrammes 
 of gold is obtained, then i ton of the ore 
 would contain 6x5 or 30 ounces of gold. If 
 on the contrary, the 6 milligrammes of gold 
 came from 4 A. T. of ore, then i ton of the 
 ore would produce but 6-^4 or i-|- ounces. 
 
 Besides the above three sets, it will be 
 found desirable to have a fourth set of grain 
 weights which may range between 1,000 
 grains and y^ grain, or 300 grains and -^-^ 
 grain. They need not be extremely accu- 
 rate. The first set will cost $10 or $11; 
 the second $2.00. It is sometimes necessary 
 to weigh a bead, button or other object 
 directly in grains, when these weights will be 
 handy. 
 
 For large weighings in pounds, the proper 
 
42 MANUAL OF ASSAYING. 
 
 weights will usually be found to accompany 
 the scales. * 
 
 (See tables of weights in Appendix.) 
 
 FURNACES. 
 
 There are three distinct and separate ope- 
 rations to be performed in an assay furnace — 
 roasting, crucible fusion, and muffle work (i.e. 
 scorification and cupellation). 
 
 In an assay laboratory of any extent, where 
 many assays are daily performed, it will be 
 advantageous, if not imperative, to have a 
 special furnace for each of the above classes 
 of work, but ordinarily the assayer can man- 
 age to get along with one. It is requisite, 
 then, that the one selected be adapted to 
 carry on all of the aforementioned operations. 
 As to the particular kind he must consult his 
 individual preference — and his purse. I can- 
 not here describe all the varieties of furnaces 
 
 * If many gold bullion assays are to be made, the assayer will 
 find it extremely convenient to have a set of so-called "gold 
 weights." (See the article " The Assay of Gold Bullion.") 
 
APPARA TUS USED IN ASSA YING. 43 
 
 which have from time to time been devised ; 
 all I can do is to speak of a few considered 
 the best. 
 
 The heat-supplying medium of a furnace 
 may be any one of three kinds of fuel, which 
 fact, therefore, will serve to form a classifica- 
 tion of the furnaces themselves into three 
 divisions : 
 
 A. Furnaces employing gaseous fuel. 
 
 B. Furnaces employing liquid fuel. 
 
 C. Furnaces employing solid fuel. ■ 
 Strictly speaking, the heat in any case comes 
 
 from the combustion of a gas, for whether the 
 fuel be liquid or solid, the burning matter is 
 either the liquid transformed into a gas, or it 
 is gas driven off- from the solid fuel. But the 
 distinctions drawn will do well enough for my 
 purpose. 
 
 A. Furnaces Employing Gaseous Fuel. 
 
 These are the so-called gas furnaces, mean- 
 ing thereby that the source of heat is our 
 common illuminating gas. But as this fuel 
 will not be on hand for the majority of those 
 
44 
 
 MANUAL OF ASSA YING. 
 
 for whom this book is written, I shall not go 
 into any great amount of detail concerning the 
 furnaces which use it. Those who desire to 
 know more about them are referred to Mitch- 
 ell, pp. 79 to loo, and to the circulars of the 
 Buffalo Dental Manufacturing Company. 
 
 Fig. i6. 
 
 The above company manufactures furnaces 
 for either crucible or muffle work, or both, 
 some of which require a blast, others only the 
 natural pressure of the gas. 
 
APPARATUS USED IN ASSAYING. 45 
 
 I cannot refrain, however, from highly prais- 
 ing one of the furnaces made by this company 
 on account of its simplicity and effectiveness. 
 It is represented in section in fig. i6. It is 
 advertised as being intended mainly for cruci- 
 ble fusions, but I have found it to work with 
 perfect success for scorifications and cupella- 
 tions. A 2f inch scorifier is the largest that 
 can be well managed in the smaller sized fur- 
 nace. By connecting the stove-pipe with a 
 chimney flue, and adding a damper, the draft 
 can be regulated perfectly. Gas supply re- 
 quired, 17 cubic feet per hour; f inch pipe 
 and tap. To operate, turn gas on full and 
 light. In about twenty minutes the furnace 
 is ready for work. For scorification, place 
 the charged^ scorifier in the furnace and put 
 on the lid. When the lead is melted, slide 
 the lid to one side to admit air, and keep it 
 so till the charge covers over. Proceed in a 
 similar manner for cupellation. 
 
 The scorifications proceed rapidly, and the 
 cqpellations can be made to do so if desired 
 
46 MANUAL OF ASSAYING. 
 
 (as in the case of lead buttons from gold 
 ores). Indeed, by the proper manipulation of 
 the damper, the supply of gas, and the lid, 
 almost any degree of fusion or oxidation can 
 be obtained. ' 
 
 The smaller sized furnace will take a cruci- 
 ble 3 by 2f inches ; the larger, one 4 by 3I 
 inches, and will use 22 cubic fiset of gas per 
 hour. Prices, $10 and $15 respectively. 
 
 B. Furnaces Employing Liquid Fuel. 
 
 There are many varieties of furnaces that 
 come under this heading, their fuel being 
 refined petroleum, gasoline, etc. As with gas 
 furnaces proper, some are intended for cruci- 
 ble fusions, others for muffle work; still others 
 are for both, The air pressure in some forms 
 is derived directly from foot bellows, in others 
 from air compressed by an air-pump. 
 
 (Consult the circulars of the Buffalo com- 
 pany already mentioned for descriptions of 
 their furnaces ; also Mitchell, pp. 72 to 78.) 
 
 Fig. 17 represents Hoskins' Hydro-carbon 
 Assay Furnace. P is an ordinary air-pump, 
 
APPARATUS USED IN ASSAYING. 47 
 
 at the bottom of which (at A) is a valve which 
 •closes automatically upon releasing the pres- 
 sure from the pump. C is a check-valve which 
 closes completely the inlet to the tank T. V 
 
48 MANUAL OF ASSAYING. 
 
 is an air-vent screw for letting off the pressure 
 when through an operation. F is the filling 
 screw. H is the pipe leading from the tank 
 to the burner D. E Is the burner-regulator, 
 terminating in a fine point, closing the orifice 
 of burner. B is a fire-brick crucible fur- 
 nace. (A mufHe furnace is also supplied.) 
 The crucible furnace will hold a crucible .4^ 
 inches high by 3^ inches across the top. The 
 muffle furnace will carry a muffle 7 inches 
 long by 2)\ wide, or one 7 inches long by 5 
 wide, according to size. Total weight of 
 apparatus packed, about 65 pounds. 
 
 The fuel is gasoline — that of 74° is best 
 — one gallon will burn from six to seven 
 hours. 
 
 To operate, close E; unscrew F and intro- 
 duce about two quarts of fluid. Replace F 
 and close V; open C one or two turns, give 
 two or three strokes to pump and close C. 
 Heat the burner D by burning a little gaso- 
 line under it (an old scorifier will do to 
 hold the gasoline); when hot enough apply 
 
APPARA TUS- USED IN A SSA YING. 49 
 
 a match and open E gradually until its action 
 is uniform. By the use of the pump as 
 above, the blast can be made of the intensity 
 desired. To stop its action, shut regulator 
 E or open screw V, or both. When not in 
 use, the vent V should invariably be left 
 open. The mouth of the burner D should 
 be from two to five inches from inlet of the 
 furnace. When putting together, screw all 
 joints up tightly and in position. For very 
 high temperature proceed as follows: 
 
 First. — Light burner as above and heat the 
 inside of furnace (crucible or muffle) to red- 
 ness, at least. 
 
 Second.^2\a.z^ the burner close to the inlet 
 of furnace. 
 
 Third. — Turn out burner with E, and im- 
 mediately turn it on again without lighting 
 it, when, if the furnace is hot enough the gas 
 will ignite inside of furnace. 
 
 Figs. 18 and 19 are representations of 
 Myers' "Jewel" assay apparatus. The first 
 illustration shows it as it is arranged for 
 
50 
 
 MANUAL OF ASSAYING. 
 
APPARA TUS USED IN ASSA YJNG. 
 
 51 
 
 
5 2 MANUAL OF A SSA YING. 
 
 scorification and cupellation work in the 
 muffle, the second for crucible fusions. The 
 manner of placing the various parts of the 
 furnace for either kind of work, is shown 
 sufficiently well by the engravings. 
 
 Directions for operating, whether for muffle 
 assays or crucible fusions. Unscrew the plug 
 on the top of the reservoir, pour in one half 
 gallon of 74° gasoline, return plug to place 
 and screw it down very tightly. Now open 
 the air-cock shown at the side of the pump 
 cylinder, and pump from twenty-five to thirty 
 times, the more the better, then close the air- 
 cock. Open the needle-valve slightly and 
 allow the gasoline to flow out into the recep- 
 tacle below the coil, till about half full, when 
 the valve is to be closed. 
 
 Ignite the gasoline in the receptacle, and 
 when nearly burned away, open the needle- 
 valve a trifle, letting out a fine stream of 
 gasoline from the reservoir, which at once 
 ignites. The coil has by this time become 
 well heated, vaporizing the gasoline as fast 
 
APPARATUS USED IN ASSA YING. 
 
 53 
 
 as it issues, and throwing a burning jet into 
 the opening of the furnace. 
 
 Pump some fifty times, and thereafter at 
 intervals of five rninutes or so, give a few 
 extra strokes. 
 
 The management of the furnace and blast 
 is easily learned after a few trials. 
 
 C. Furnaces Employing Solid Fuel. — In 
 this class are found the best known furnaces, 
 using as fuel, wood, charcoal, coke, hard and 
 soft coal, or, mixtures of them. 
 
 ^£^1 
 
 Fig. 20. 
 
 The Battersea furnace is of fire clay, made 
 
54 MANUAL OF ASSAYING. 
 
 in sections and bound with iron bands. Fig. 
 20 is a sectional view of the muffle furnace, of 
 whicli the following sizes are obtainable in 
 this country; 
 
 
 Height, 
 
 Diameter, 
 
 Sizes 0/ MtiJifles, 
 
 
 
 No. 
 
 inches. 
 
 inches. 
 
 in inches. 
 
 
 Price. 
 
 c 
 
 27 
 
 14 'A 
 
 g long, 3^ high, 5;^ 
 
 wide 
 
 $25 00 
 
 D 
 
 28J^ 
 
 is'A 
 
 10 "4 "6 
 
 " 
 
 30 00 
 
 E 
 
 29>^ 
 
 16X 
 
 12 "4 "6 
 
 *' 
 
 35 00 
 
 F 
 
 30 
 
 17K 
 
 14 "5 "8 
 
 " 
 
 40 00 
 
 K 
 
 48 
 
 23 
 
 15 "6 "9 
 
 " 
 
 80 00 
 
 Judsons Sectional Assay Furnace (patent- 
 ed) is represented in fig. 21. Two sizes are 
 specified. Dimensions in inches : 
 
 , Muffle V 
 
 No. High. Wide. Deep. Long. ]Vide. High. 
 
 1 36 18 13 12 6 4 (Battersea J) 
 
 2 42 22 16 15 96 (Battersea L) 
 
 No. I is made of part steel and part iron 
 (weight about 300 pounds, price $45), or all 
 steel (weight 250 pounds, price $52). No. 2 
 is manufactured both entirely of cast iron, 
 and part iron and part steel (the latter weighs 
 about 450 pounds, price $60). 
 
 For details concerning the preceding three 
 kinds of furnaces consult the various cata- 
 logues and circulars. 
 
APPARATUS USED IN ASSA YING. 
 
 55 
 
 Fig. 21. 
 
 Brown s Portable Assay Furnace. Fig. 22. 
 — This furnace consists of a sheet-iron frame 
 27 inches high and 14 inches square, lined 
 with fire-brick in sections, the interior being 
 smooth and straight from top to bottom. 
 The cover is cast-iron, and is ridged to lessen 
 the danger of cracking. The muffle door is 
 cast-iron, and is fitted with a circular open- 
 ing, filled with mica, that the operations going 
 
56 
 
 MANUAL OF ASSAYING. 
 
 on within the mufifie may be seen when the 
 door is closed. The draft-doors are also of 
 cast-iron, and are provided with wheel open- 
 
 Fit 
 
 ings to further regulate the draft. The circu- 
 lar holes at bottom are in all four sides of the 
 furnace, and serve to keep cool the true bottom 
 torn of the furnace upon which the ashes fall. 
 
APPARATUS USED IN ASSAYING. 57 
 
 The muffle seen in the opening rests equally 
 upon the fire-brick in front and in the rear of 
 the furnace, leaving a space of \ inch between 
 the end of the muffle and the brick to allow 
 the passage of fumes. 
 
 The grate is formed of cast-iron- bars, lo 
 inches long, i inch square, 6 in number, rest- 
 ing upon a cast-iron frame. 
 
 The space below the true bottom is to be 
 filled with fire-brick or sand or other material 
 convenient. 
 
 The chimney hole is 5 inches in diameter, 
 thus accommodating a stove-pipe of same 
 dimensions. The bottom of this hole is 17 
 inches from the true bottom of the furnace, 
 and 8 inches from the bottom level of the 
 muffle. 
 
 There is a handle upon each side of the fur- 
 nace to allow more convenient handling. 
 
 The furnace can take either H or J muffle 
 of the Battersea pattern, 
 
 SizeH. Length, io>^ in. Width, 5^ in. Height, 3% in. 
 
 " J. " 12 " " 6 " "4 " 
 
58 MANUAL OF ASSAYING. 
 
 but Is best adapted for size J, the most com- 
 monly used muffle. Entire weight of furnace 
 boxed is 125 pounds. 
 
 The above furnace possesses the following 
 advantages : 
 
 1st. Simplicity. Having no complicated 
 parts to get out of order, 
 
 2d. Usefulness. It can be used both for 
 muffle work and for crucible operations. 
 
 3d. Capacity. There is no other furnace 
 manufactured of similar dimensions and weight 
 which can accommodate so large muffles, and 
 consequently produce so much work and so 
 rapidly. 
 
 4th. Durability. Being made of heavy 
 sheet-iron, it cannot be broken by handling 
 nor injured by heating. 
 
 5th. Adaptability. Any fuel may be em- 
 ployed for which the draft of the chimney is 
 sufficient. 
 
 6th. Light weight. Boxed, this furnace 
 weighs but 125 pounds, as against 250 to 400 
 pounds of other furnaces. 
 
APPARATUS USED IN ASSAYING. 59 
 
 7th. Cheapness. This furnace is from one- 
 third to two-thirds cheaper than any other 
 furnace that will do as good work. Boxed 
 for transportation, $20. 
 
 For permanent fui-naces of brick, etc., 
 whether to be used for roasting, fusion, scori- 
 fication and cupellation work, see Ricketts. 
 pp. 21-26, and Mitchell pp. 57, 63, etc. The 
 various stamp mills, smelting and sampling 
 works, and mining corporations scattered 
 throughout the West, have usually permanent 
 furnaces burning coke, charcoal, soft or hard 
 coal, which may profitably be imitated. 
 
 Furthermore, many a peripatetic assayer 
 has conjured up a temporary furnace of clay, 
 adobe, or home-made bricks, using a tile or 
 large crucible for a mufifle, to meet an emergen- 
 cy, and when its days of usefulness were over, 
 left it to decay and ruin. On such occasions, 
 necessity is indeed the mother of invention. 
 
 FURNACE TOOLS. 
 
 Crucible Tongs. — For placing in, and re- 
 
6o 
 
 MANUAL OF ASSAYING. 
 
 moving from, the furnace, crucibles. The as- 
 sayer will need one large and strong pair, of 
 wrought iron, 24 to 36 inches long, the grip- 
 
 FiGS. 23 and 24. 
 
 ping ends of which may be curved or straight, 
 like figs. 23 and 24, or tongs can be procured 
 
 Figs. 25 and 26. 
 
 of either one of the two forms given in figs. 
 25 and 26. Either one, however, of the two 
 first mentioned, will do very well. 
 
APPARA TUS USED IN ASSA YING. 
 
 6r 
 
 A smaller pair, from- 15 to 18 inches in 
 length, for lifting small crucibles and large 
 scorifiers, for placing lead buttons in the cu- 
 pels, and for opening and shutting the doors 
 of the furnace, is invaluable (fig. 27). 
 
 Fig. 27. 
 
 A Still smaller pair of 8 inches in length 
 (fig. 28), for managing the 
 doors of the furnace, is 
 handy, but not absolutely 
 necessary. 
 
 Scarifier Tongs. — The correct shape is here 
 given (fig. 29). The length about 24 inches. 
 
 Fig. 28. 
 
 Fig. 29. 
 
 The curved arms fit the bottom of the scori- 
 fier, the long arm extending across the top. 
 
62 
 
 MANUAL OF ASSAYING. 
 
 The best material for these tongs is steel, and 
 they should not possess too much spring. 
 Two or three sizes should be procured, to ac- 
 commodate the various sizes of scorifiers. 
 
 Fig. 30 represents Judson's patent 
 steel scorification tongs arranged for 
 lifting scorifiers from the rear of a 
 muffle without disturbing those in 
 front. 
 
 Cupel Tongs. — Several forms are 
 permissible. A common pattern is 
 shown in fig. 31. In using these 
 particular tongs, care should be 
 taken to secure a firm grasp of the 
 cupel, lest it slip through the tongs 
 and be broken, and the bead be lost. 
 On the other hand, too much press- 
 ure may crush the cupel. 
 
 With these tongs the grip should 
 be made nearer the top than the 
 bottom of the cupel, for should the 
 operator happen to grasp with it a 
 Fig. 30 cupel below the latter's centre of 
 
APPARA TUS USED IN ASSA YING. 63 
 
 Fig. 31. 
 
 gravity (especially when the cupel is soaked 
 with litharge), it will probably turn over, 
 again giving a chance for loss of the bead of 
 precious metals. 
 
 The form next figured (fig. 32) is not 
 
 Fig. 32. 
 
 likely to cause the above accident, nor quite 
 so liable to crush the cupel, and fig. 33 illus- 
 trates a better pair than either of the preced- 
 ing. 
 
 Fig. 33. 
 
 Fig. 34 represents Judson's patent cupel 
 tongs. 
 
64 
 
 MANUAL OF ASSAYING. 
 
 Whatever pair of tongs is used should be of 
 steel or wrought iron, light weight 
 with not too strong a spring, 
 length from i8 to 24 inches, and 
 with a strong guide. 
 
 For considerable of my work I 
 have used, instead of tongs, the 
 cupel shovel (fig. 35), and cupel 
 rake (fig. 36). The curve of the 
 latter fits the cupel. By means 
 of these two implements, one or 
 two cupels can be easily and 
 quickly run in or out of the muffle 
 without danger of damage. They 
 can be of light weight wrought 
 iron, and about 24 inches long. 
 For carrying a half dozen cupels 
 at a time, a second shovel with 
 the blade six to eight inches long 
 
 Fig. 34. would be serviceable. 
 
 Fig. 35. 
 
APPARA TUS USED IN ASSA YING. 
 
 65 
 
 ^ 
 
 Fig. 36. 
 
 Scarifier or Scarification 
 Moulds, Slag Moulds, or 
 Pouring Plates. — Two forms 
 are here presented. Fig. 37 
 is of cast iron and has nine 
 holes; the same is furnished 
 with but six. Fig. 38- is also 
 of iron, and has the advan- 
 tage of collecting the lead 
 better together, and the dis- 
 advantage of having but 
 three receptacles. 
 
 Fig. 37. 
 
 Fig. 38. 
 
 Any hardware merchant can provide a 
 very good substitute for either of the above 
 
66 -MANUAL OF ASSAYING. 
 
 in the shape of a so-called ''gem-plate" gener- 
 ally with twelve cavities. 
 
 Similar moulds can be procured of heavy 
 copper, which has the advantage of not sud- 
 denly chilling the slag and thus causing it to 
 retain small pellets of the lead, but they are 
 quite expensive, and if the iron plates are 
 warmed before using, they will serve quite 
 as well. 
 
 I do not recommend the practice of paint- 
 ing the interiors of the cups with ruddle or 
 chalk washes. 
 
 The utility of scorification moulds is obvi- 
 ous; by employing them the time of cooling 
 is greatly diminished, and the scorifiers can 
 (but they had better not) be re-used. 
 
 Large moulds for receiving fused crucible 
 charges can be procured (for example a 
 plumber's lead pot), but as mentioned else- 
 where, unless crucibles are rare, they are 
 not necessary. It is the custom in some 
 assay offices to pour a crucible fusion into 
 one of the cavities of the scorification mould 
 
APPARATUS USED IN ASSAYING. 67 
 
 with conical cups (fig. 38). The lead but- 
 ton sinks to the bottom of the mould and 
 the excess of slag^ fused salt, etc., runs over 
 the top and into any convenient receptacle. 
 Muffle Scraper. — Shown in fig. 39. Made 
 
 Fig. 39. 
 
 of wrought iron, length 24 inches. The cupel 
 shovel spoken of can be used for conveying 
 sand or bone ash into the muffle whenever 
 lead has been spilled upon its floor, and the 
 scraper employed for bringing out the pasty 
 mass formed, and smoothing down the sur- 
 face of the floor of the muffle. 
 
 Pokers. — One long straight one, 32-36 
 inches, of f inch wrought iron (fig. 40), a 
 
 Fig. 40. 
 
 short one, 18 inches, with end bent, for 
 muffle work, and a third ordinary poker, for 
 stirring the fire, are desirable. 
 
68 MANUAL OF ASSAYING. 
 
 APPARATUS USED IN THE FURNACE. 
 
 Muffles. — The term muffle is applied to 
 that piece of apparatus figured here in vari- 
 ous forms, in which are performed the opera- 
 tions of roasting, scorification, cupellation, 
 etc. Muffles are made of iron, plumbago, 
 or a refractory mixture {i.e. sand and fire- 
 clay), most generally the latter. They can be 
 procured in the market in almost every con- 
 ceivable size (the price lists enumerating some 
 fifty), besides which they can be made to or- 
 der of any special dimensions. 
 
 The air-apertures are in the sides in some 
 
 ^. (fig. 41), in the end as a sin- 
 
 " gle opening (not shown in the 
 
 cut) in the form most favored 
 
 Fig. 41. in this country (fig. 42). 
 
 Still other muffles are open entirely at both 
 
 ends, so that their contents can 
 
 be manipulated as well from 
 
 the back as from the front. 
 
 Fig. 42. Any muffle can be easily con- 
 
 
APPARATUS USED IN ASSAYING. 69 
 
 verted into this form by sawing off the closed 
 end. 
 
 The size of the muffle employed will be de- 
 termined by the size and make of the furnace. 
 
 In case the furnace is so constructed that 
 the muffle can easily be taken out (and it is 
 well to have it out during the firing up and 
 first heating), then to avoid danger of crack- 
 ing it by sudden heat it is best to place it on 
 top of the furnace to warm it somewhat before 
 putting it in position. 
 
 False floors to the muffle are obtainable, 
 and save the real floor from injury due to 
 spilled lead, etc. They are made of same 
 material as the muffles. 
 
 Crucibles. — These vessels are made of vari- 
 ous materials : black lead (graphite or plum- 
 bago), French clay, Hessian sand, charcoal- 
 lined {i.e. Hessian sand crucibles with a lining 
 of charcoal and molasses), quick lime, a mix- 
 ture of magnesia and chloride of magnesium, 
 alumina, and finally those for very special 
 purposes, of porcelain, iron, platinum, gold or 
 
70 
 
 MANUAL OF ASSA YING. 
 
 Fig. 43. 
 
 silver. It is but few of these varieties that 
 are needed for the assayipg of gold, silver, 
 copper and lead ores, and these I now specify. 
 The so-called clay or sand cru- 
 cibles are the ones fitted for the 
 assaying of the ores of the four 
 metals named. They occur in two 
 forms, round and triangular (figs. 
 43 and 44), with covers to match. 
 Almost, any size can be obtained 
 from some one of the manufactu- 
 rers. In giving the charges for cru- 
 cible work I have generally indicated 
 the sizes of crucibles needed. The 
 most commonly used crucibles will 
 range between 3^^ and \\ inches in 
 height, and between 2^ and 4!^ inches 
 across. For an ordinary crucible 
 charge of one assay ton and fluxes, 
 a crucible \\ inches high by 4^^ across 
 will be about right. 
 
 Fig. 45 shows the form of the 
 French clay or Beaufay crucible or 
 " fluxing pot," 
 
 Fig. 44. 
 
 Fig. 45. 
 
APPARATUS USED IN- ASSAYING. J I 
 
 For muffle lead the specially shaped cruci- 
 bles figured here (fig. 46) are desirable. The 
 largest size can also be used for fusions of 
 gold and silver ores in muffle. They are made 
 in three sizes. Those furnished by 
 the Battersea company are known as 
 the " Colorado " crucibles. Those 
 manufactured by the Denver Fire 
 Fig. 46. Clay Co. are known as 5, 10 and 20 
 gramme crucibles. The sizes are as follows ; 
 dimensions approximate : 
 
 AA, " Colorado " of Battersea Co. or 5 gramme of Denver Fire 
 Clay Co., 2% inches high; 2% inches across. 
 
 A, " Colorado " of Battersea Co. or 10 gramme of Denver Fire 
 Clay Co., 3 inches high; 25^ inches across. 
 
 B, " Colorado " of Battersea Co. or 20 gramme of Denver Fire 
 Clay Co., 2)% inches high; 3 inches across. 
 
 Roasting Dishes. — These are made of re- 
 fractory clay or black lead, of the form indi- 
 cated (fig. 47). They should be 
 quite shallow. They are used for 
 the roasting of ores containing 
 much antimony, arsenic, sulphur and zinc. 
 They are furnished in sizes ranging from if 
 
72 MANUAL OF ASSAYING. 
 
 to 8 inches in diameter. The 3-inch dish is 
 suitable for roasting \ A. T. The 5 and 6 
 inch sizes can be employed with satisfaction 
 for open air roastings of i, 2 or more A. T. 
 (for crucible work), in place of the frying-pan. 
 
 Scarifiers. — These articles are made of a 
 material similar to that of the clay 
 roasting dishes. Fig. 48 shows the 
 
 '° '^ right shape. They should be some- 
 what shallow ; in texture uniform, and free 
 from cracks and holes. 
 
 They can be procured in sizes varying from 
 I inch to 5 inches in diameter. 
 
 The best size for all ordinary scorifications 
 is the 2f inch (if the muffle is wide enough 
 to admit it). This size takes from \ X.o \ h. 
 T. of ore, according to its gravity. The 2\ 
 inch is well adapted for re-scorifications, that 
 is, for reducing in size too large lead but- 
 tons. It can also be employed when very 
 little of the ore is to be worked, say -^ A. T. 
 
 Have the 2| inch in large quantity, with 
 one half as many 2\ inch and perhaps a few 
 
APPARA TUS USED IN ASSA YING. 73 
 
 2\ inch. For certain other purposes it is 
 advisable to have on hand a few of the 3 and 
 3^ inch sizes. 
 
 As the manufactured scorifiers will stand a 
 great deal of rough handling without injury, 
 and since they are well made and cheap, it is 
 better to purchase them, rather than to 
 attempt their home manufacture which is not 
 a very easy thing. 
 
 Cupels. — Among the most useful articles 
 the assayer possesses. They are employed to 
 absorb oxides of almost all the metals save 
 those of gold and silver, thus leaving these 
 two metals behind in a state of comparative 
 purity. Lead is the metal whose oxide, 
 litharge, they absorb in great quantity. Any 
 substance which will absorb these various 
 oxides would do, but for many reasons, burnt 
 tones or bone-ash is preferred. Good bone- 
 ash is so easily and cheaply obtained that it 
 seems a waste of time to more than indicate 
 the process whereby the assayer himself may 
 make his own supply. In brief, horse or 
 
74 MANUAL OF ASSAYING. 
 
 sheep bones are boiled repeatedly in water, 
 their organic matter (grease, carbon, etc.) 
 burnt away, they are then finely ground, 
 sifted and washed. (Mitchell, pp. 133-4.) 
 
 Very good cupels can be purchased in sev- 
 eral sizes, and when they are good, can b'e 
 safely packed and transported. 
 
 The one chief objection to purchased 
 cupels is their expense, therefore ordinarily 
 it is cheaper to make them, to do which I 
 now give directions: 
 
 The bone-ash which can be obtained in 
 bulk and of several grades, is mixed, say one 
 pound at a time, with a strong solution of 
 pearl-ash (or carbonate of potash) in warm 
 water, till the mixture adheres well together, 
 though it must not be at all pasty. (The 
 right degree of moisture is hard to describe 
 but easy to acquire.) When a portion of the 
 mixture is squeezed in the hand, it should 
 cake together (somewhat like half-melted 
 snow) and show the imprint of the fingers. 
 Now sift through a common flour sieve, place 
 
APPARA TUS USED IN ASSA YINC. 75 
 
 the cupel ring upon a block of wood (having 
 a large piece of brown paper spiead out 
 below all), fill about flush with the surface 
 with the sifted bone-ash and strike the 
 plunger into the ring four or five times mod- 
 erately heavily. Turn the plunger around in 
 the ring once or twice and push the cupel 
 gently out. A little practice will soon enable 
 the assayer to turn out perfect cupels. 
 
 The moisture remaining in the cupels can 
 be driven out by placing them on the top of 
 the furnace after a day's running, or, what is 
 better, by allowing them to dry in the normal 
 atmosphere of the room or by exposure to 
 the sunlight. Cupels thus slowly dried are 
 less likely to crack on using. 
 
 The texture of the cupel, that is, its degree 
 of porosity, depending on the fineness of the 
 bone-ash and amount of compression, is quite 
 important. If too fine bone-ash is used, the 
 cupel will crack (or " check," as it is some- 
 times termed), in the muffle ; if too coarse, 
 the cupel will absorb silver, causing loss. 
 
76 MANUAL OF ASSA YING. 
 
 Therefore a medium grade had best be 
 chosen. The above two difficulties are in a 
 measure obviated by making the body of the 
 cupel, that is, the lower two-thirds, of coarse 
 material, and the upper third of fine. 
 
 If the cupel is too compact, cupellation 
 proceeds too slowly ; if tod loose or porous, the 
 cupellation proceeds too rapidly, causing a cer- 
 tain absorption of silver with the lead. As in 
 everything else, experience is the best teacher. 
 
 Theybrm of the cupel is immaterial. Fig. 
 49 represents the one which I prefer 
 on account of the ease with which it 
 Fig. 49. can be removed from the mould. 
 
 A cupel with diameter of i^ inch is a con- 
 venient size. 
 
 Annealing Cups. — Shown in fig. 50. Used 
 in the assay of gold bullion. Should 
 be well made, light but strong. Vari- 
 FiG. 50. ous sizes can be obtained. 
 
 Annealing Plate. — Employed for annealing 
 a number of slips at once, in the gold bullion 
 assay. In size about 6 inches long, 2 wide 
 
APPARA TUS USED IN ASSA YING. 77 
 
 and f inch thick. May be made of an old 
 muffle floor rubbed down. Can be purchased 
 of either fire clay or plumbago. 
 
 APPARATUS OF GLASS AND PORCELAIN. 
 
 Sample Bottles. — A number of these, of two, 
 four, six and eight ounce capacity, with wide 
 mouths and cork stoppers, are desirable for 
 pulverized samples of ores. 
 
 Re-agent Bottles. — The dry re-agents are 
 best kept in wide-mouthed bottles (known as 
 "salt mouths"), glass-stoppered, thus prevent- 
 ing the admission of dust and moisture. 
 
 Stone-ware crocks of various sizes can be 
 employed instead of the bottles, and will, of 
 course, contain greater quantities. 
 
 Fruit-jars with threaded necks and metallic 
 caps will stand transportation better than the 
 bottles, and tin cans or wooden boxes will 
 pack more closely and last longer than either. 
 Circumstances will alter cases if the labora- 
 tory is to be more of a traveling than a fixed 
 one. 
 
78 
 
 MANUAL OF ASSAYING. 
 
 Whatever receptacles are used, they should 
 be properly labelled. 
 
 Bottles, of course, are necessary for, the wet 
 re-agents. The distilled water can be pre- 
 served in clean demijohns enclosed in wicker- 
 work, or in clean stone jugs. 
 
 Wash Bottle. Fig. 51. — To 
 contain distilled or pure water. 
 A quart is the best size. By 
 blowing in at the opening a, a 
 fine stream of water is thrown 
 out through b. 
 
 Watch Glasses. Fig. 52. — 
 More correctly known as clock- 
 glasses. A pair is desirable 
 
 to place in the scale pans of the 
 ore scales, to keep injurious sub- 
 stances away from contact ; in di- 
 ameter they should be slightly less than that 
 of the pans. 
 
 Porcelain Capsules or Crucibles. — For hold- 
 ing the bead of gold and silver while 
 being parted. Two sizes are conven- 
 FiG. 53- \^x\'i, one being i inch in diameter across 
 
 Fig. 51. 
 
APPARATUS USED IN ASSAYING. 79 
 
 top by f inch in depth, the other \\ inch dia- 
 meter by i]^ deep. A good shape is that 
 here figured. A dozen of each size will last 
 some time. 
 
 Test Tubes. — Used in qualitative tests. It 
 is well to have some of four, six and eight 
 inches in length. A rack to hold them is con- 
 venient. Some assayers employ them for 
 parting gold and silver beads. 
 
 Parting Flasks (or Boiling Flasks). — A 
 small flask, capacity \ ounce, of form 
 as figured, is sometimes used for part- 
 ing gold and silver beads, instead of 
 Fig. 54. test-tubes or porcelain capsules. At 
 least three will be needed. Round-bottomed 
 flasks are also frequently used. 
 
 Matrasses. — Flasks of the shape delineated 
 in fig. 55 and used for the parting of 
 gold bullion, are generally termed ma- 
 trasses. It is quite important for the 
 purposes of manipulation that the neck 
 FiTss. of the flask should fit snugly into the 
 annealing cups employed. Can be held by a 
 wooden clamp. 
 
8o 
 
 MANUAL OF ASSAYING. 
 
 Glass Beakers. — Will 
 be needed in the copper 
 and other analyses, chlor- 
 ination and other tests, 
 etc. They should be 
 lipped (fig. 56), and pre- 
 ferably of thin material 
 to stand heat. Several 
 nests may be wanted. 
 (ilass Funnels. — For analyses of 
 different kinds. Should be of an 
 angle of 60° (fig. 57). 
 
 Glass Slurring Rods. — Very use- 
 ful. Cut up a long glass rod into 
 Fig. 57. various lengths, and round each 
 end by holding in a lamp or gas flame for a 
 minute or so. 
 
 Flasks. — One will be wanted for the chlori- 
 nation assay of gold. Several sizes can be 
 made use of, for wash-bottles, to retain solu- 
 tions for any length of time, etc. Should be 
 of thin glass. 
 
 Separatory Funnel. — See " Chlorination As- 
 
 say for Gold," in appendix. 
 
APPASA TVS USED IN ASSA YING. 
 
 8l 
 
 Casserole. Fig. 58. — Of 
 porcelain. Can be put to 
 many uses, as small evapo- 
 
 . Fig. 58. 
 
 rations, etc. 
 
 Pipettes. Fig. 59. — A 10 c.c. and a 5 c,c. 
 
 Fig. 59- 
 
 will be required in the copper analysis. They 
 can be home-made by drawing down to a 
 fine opening one end of a glass tube, and 
 rounding the other. 
 
 Mortars and Pestles. — Small 
 sizes of these are useful in pul- 
 verizing re-agents, etc. Their 
 material may be either glass (fig. 
 60) or porcelain ; shape as represented. 
 
 Fig. 6d. 
 
 MISCELLANEOUS APPARATUS. 
 
 Note-books. — Indispensable. Nothing should 
 be left to the memory, but everything impor- 
 tant relating to the assay of an ore should be 
 down in black and white. 
 
82 MANUAL OF ASSAYING. 
 
 The number of the ore, its character, the 
 charge for the furnace, conduct in the fire, 
 results of the various operations, as shown by 
 the crucibles, scorifiers, cupels, slags, buttons, 
 beads, etc., and all calculations, should be 
 taken note of. 
 
 Gummed Labels. — An assortment of various 
 shapes and sizes will be found extremely con- 
 venient. 
 
 Boxes. — Of pasteboard, 5^ inches long, 3^ 
 wide and 2 high, to be used for pulverized 
 samples. Paper boxes, tin boxes, paper bags 
 and cloth bags are also used. 
 
 Paper. — Sheets of heavy brown or manilla 
 paper for the mixing of ore samples are neces- 
 sary. 
 
 Sheets of black glazed paper can be used 
 instead, but it is better to reserve these for 
 the mixing of charges, as they are a little too 
 delicate for rough work. Some assayers use 
 pieces of sheet rubber, rubber cloth or oil- 
 cloth. 
 
 Whatever kind be employed, see that it 
 
APPARATUS USED IN ASSAYING. 83 
 
 has no holes to allow loss of sample or charge. 
 
 Tissue paper for wrapping up borax glass 
 into pellets, and for enfolding minute gold 
 and silver beads for flattening, will be needed. 
 Filter-paper is indispensable for filtrations; 
 also valuable for removing small quantities 
 of moisture from the interiors of the porce- 
 lain capsules in the operation of parting. 
 Clean blotting-paper will do for the latter 
 purpose. 
 
 The filter-paper may be obtained in sheets 
 or cut round of any size wanted. 
 
 Brushes. — Several are necessary. First, in 
 case the rubbing-plate is employed, a large 
 brush such as is used by painterk is invalua- 
 ble. 
 
 For brushing charges from the scale-pans 
 or glazed paper, a medium size camel's hair 
 is wanted, and for brushing the scale-pans of 
 the delicate balances a very fine camel's hair 
 brush is needed. 
 
 Pincers. — A few pairs of varying sizes are 
 handy. One of about 8 inches in length. 
 
84 MANUAL OF ASSAYING. 
 
 Strongly made of wrought-iron, a 4-inch pair 
 of brass, and a third pair with limbs running 
 down to a fine point, for picking up minute 
 gold and silver beads, will suffice. 
 
 Hammers. — While the assayer can get along 
 
 Fig. 61. 
 
 with one or two hammers, it is better to be 
 provided with four or five. A heavy 5-pound 
 sledge-hammer, a couple of smaller ones of 
 about two pounds, one of them having one 
 sharp edge and a square face (fig. 61), the 
 other with both faces blunt, a small hammer 
 for breaking crucibles and scorifiers and flat- 
 tening buttons, and a \ ounce sharp-edged 
 hammer for trimming small specimens and 
 flattening gold and silver beads, are very con- 
 venient. 
 
 A sharp hatchet for kindling-wood and a 
 
APPARATUS USED IN ASSAYING. 85 
 
 dull one for breaking coke complete the cate- 
 gory. 
 
 Anvils. — A miniature blacksmith's anvil 
 (fig. 62), weighing lo pounds, and properly 
 
 Fig. 62. 
 mounted on a block, will be in constant de- 
 mand. A simple yet satisfactory method of 
 mounting the anvil has been of long-time use 
 in my laboratory. An oaken block, 30 inches 
 high by 12 inches through in both the other 
 directions, has a frame of i inch wood 
 screwed to its sides at the top, rising one 
 inch above the surface. On the top of the 
 block is nailed a half inch thickness of 
 rubber belting, leaving one-half inch space 
 between its surface and the upper edge .of 
 the surrounding frame. The anvil is screwed 
 down to a piece of 2-inch oak fitting this 
 space. The oaken block furnishes a firm 
 
86 MANUAL OF ASSA YING. 
 
 support for the anvil, the rubber deadens the 
 sound of blows, and by lifting off and put- 
 ting aside the anvil and its bottom, the block 
 serves as a convenient table for breaking ores 
 in the mortars. 
 
 A flat plate of steel, if by \\ inches and 
 \ inch thick, on which are to be flattened the 
 gold and silver beads, is useful. 
 
 Ring-stand. — This implement, 
 made of cast-iron, is useful for 
 lh»^{»=^^5 many purposes ; to hold a wire 
 triangle that supports the por- 
 celain capsule used in parting, 
 to support a sand-bath, wire- 
 gauze, etc. Fig. 63 shows one 
 ~^i pattern. 
 
 Fig. 63. 
 
 Fig. 64. 
 
 Wire Triangle. — Of twisted 
 wire (best of platinum), in 
 shape as figured, for support- 
 ing capsules, etc. It may also 
 be strung through pieces of 
 pipe stems. 
 
APPARATUS USED IN ASSAYING. 87 
 
 Sand-baths. — Any flat plates of tin or iron 
 /filled with sand. Their use is to distribute 
 the heat around any vessels imbedded in the 
 sand. 
 
 Wire-gauze. — Three-inch squares of iron 
 wire gauze are used for same purposes as the 
 sand-baths. 
 
 Burners, Lamps and Stoves. — When gas 
 can be procured, the Bunsen 
 burner, fig. 65, is the best supplier 
 of heat for small purposes. By 
 turning the ring at the bottom so 
 as to close the holes, a light-giving 
 flame is produced ; by leaving the 
 holes open, there is obtained a '°' ^" 
 heating flame due to the more perfect com- 
 bustion. A large alcohol lamp is the best 
 substitute for the Bunsen burner. 
 
 Stoves for burning gas, gasoline, kerosene, 
 etc., etc., I leave for individual selection. 
 
 Frying Pan. — Aside from any culinary 
 importance, this kitchen utensil serves a use- 
 ful end in receiving melted borax glass; 
 
88 MANUAL OF ASSAYING. 
 
 spreading the latter out that it may cool in a 
 thin sheet. 
 
 It is ajso occasionally employed in the 
 roasting of sulphurets, etc., on a compara- 
 tively large scale. 
 
 In either case coat the pan with chalk or 
 ruddle paint. 
 
 Blowpipe. — For testing minerals and for 
 fusing gold and silver together. There are 
 many forms of this important little instru- 
 ment, but a plain curved one is as satisfactory 
 as any for ordinary blow-piping. (Consult 
 the works on Blowpipe Analysis.) 
 
 Cupel Moulds. — For making cupels. These 
 are made of either steel or brass, but prefera- 
 bly o^ the latter, since they do not rust so 
 quickly. A mould generally consists of three 
 parts, the plunger or pestle, which is convex at 
 the bottom to form the concavity of the cupel, 
 the ring into which the plunger partly or wholly 
 slips, and a bottom plate upon which the ring 
 rests. In some moulds this bottom plate is 
 circular and fits into the ring. 
 
APPARATUS USED IJSr ASSAYING. 89 
 
 Fig. 66 represents a good form, 
 which is of brass, and is furnished 
 in sizes that make cupels of i|- and 
 i^ inches diameter. It has no bot- 
 tom plate, but a smooth block of 
 hard wood will serve equally well. 
 The cupel this mould furnishes has 
 its sides at right angles to the base 
 (see fig. 49). One advantage this 
 form of mould possesses is that by fig. 66. 
 using more or less bone-ash, cupels of vary- 
 ing thicknesses can be obtained by reason of 
 the plunger sliding in the ring, which is not 
 the case with all others. 
 
 A special machine has been devised for 
 making cupels, but I am not at all certain 
 that it turns them out any better than does 
 the common mould, nor more rapidly. If 
 greater pressure is needed than that given 
 by the hammer or mallet, a second - hand 
 letter press might be utilized, by knocking 
 off the upper plate and making a few altera- 
 tions. 
 
go 
 
 MANUAL OF ASS A YING. 
 
 Shears. — For cutting gold and silver bull- 
 ion, sheet silver, lead-foil, etc. Should be 
 
 Fig. 67. 
 
 strong and have a keen cutting edge. Fig. 
 67 represents a good form. 
 
 Scissors for cutting filter papers, etc., will 
 be wanted. 
 
 Rolls for thinning out gold and silver bull- 
 ion are more needed in a mint than else- 
 where. 
 
 Magnifying Glass. — Pocket size very useful. 
 
 Magnet. — A small pocket magnet will come 
 in play very often both in the field and labora- 
 tory. Metallic iron, magnetic oxide of iron, 
 nickel and cobalt are attracted by it. 
 
 Ingot Moulds for gold, silver and lead can 
 be obtained in twenty or more sizes. 
 
 Steel Alphabets and Figures. — The bullipn 
 assayer will need these for stamping bullion. 
 
APPARA TUS USED IN ASSA YING. gl 
 
 They should comprise the numerals from o to 
 9, an alphabet, and certain stamps in one 
 piece, as " Gold," " Silver," " Fine," " Value," 
 " Total," " No.," "Oz." and " $." In size the 
 above may vary from -^ inch to |- inch. Steel 
 dies with name of mine, company, assayer, 
 etc., can be procured as desired. 
 
 Cold Chisels. — One large (i inch diameter) 
 and one small one (^ inch) are useful. 
 
 Miners Gold-washing Pans. — See "Pan 
 Test for Gold," in appendix. 
 
 Filter Stands. Fig. 68. — 
 For holding funnels. Wood- 
 en ones are easily obtained . 
 or made. \^ ? "^jS^- 
 
 Battery, Platinum Vessels, ™ 
 
 etc. — See "Copper Analysis." 
 
 Amalgamation Mortar or 
 laboratory "arrastre." — It is 
 of cast iron, and is simply a 
 mortar with its pestle revolv- 
 ing on a spindle. There are 
 other forms procurable. See 
 "Amalgamation Assay," in appendix 
 
 J 
 
92 MANUAL OF ASSA YING. 
 
 Iron Retorts. — They are used for distilling 
 off the mercury from an amalgam. Can be 
 found in sizes ranging from \ to 24 pints. 
 The smallest size will do for ordinary work. 
 
 Chamois Skin or any other fine leather. 
 — Used in squeezing out the free mercury 
 from an amalgam. 
 
CHAPTER II. 
 
 RE-AGENTS USED IN ASSAYING. 
 
 Under this heading I purpose to speak of 
 those re-agents (or substances which react), 
 necessary for the assaying of gold, silver, 
 copper and lead ores. I shall tell what they 
 are, how they act, when to be used and with 
 what object, and, finally, how to prepare 
 them when preparation is necessary. 
 
 DRY RE-AGENTS FOR ASSAYING. 
 
 The dry re-agents needed for the assays 
 described in this book are sixteen in number, 
 as follows : 
 
 1. Bi-carbonate of soda. 
 
 2. Carbonate of potash. 
 
 3. Cyanide of potash. 
 
 4. Borax glass and common borax. 
 
 5. Flour. 
 
 6. Black flux substitute. 
 
 7. Argol (or cream of tartar). 
 
94 
 
 MANUAL OF ASSAYING. < 
 
 8. Common salt. 
 
 9. Carbonate of ammonia. 
 
 10. Nitre. 
 
 11. Wood charcoal. 
 
 12. Silica. 
 
 13. Lead (sheet and granulated). 
 
 14. Litharge. 
 
 15. Iron (nails and wire). 
 
 16. Silver. 
 
 /. Bi-Carbonate of Soda (chemical name, 
 hydro-sodic-carbonate). — This is the ordinary 
 commercial bi-carbonate, and needs no prepa- 
 ration, save to be ground free from lumps. It 
 is employed in the crucible assays of gold, sil- 
 ver, copper and lead ores. Its action is de- 
 sulphurizing (that is, it removes the sulphur 
 from ores fused with it, forming sulphide of 
 soda), and oxidizing (that is, converting cer- 
 tain metals, as iron, tin and zinc, which may 
 have been in the ores treated, from the metal- 
 lic state to their corresponding oxides), by 
 means of the carbonic acid it contains. Be- 
 ing so readily fusible, it acts as a wash to 
 
RE-AGENTS USED IN ASSAYING. 95 
 
 rinse down from the sides of the crucible any 
 matters which may be adhering thereto. 
 
 Finally, it has a most important bearing as 
 & flux, meaning that it forms a fusible com- 
 pound with certain impurities of the ores, as 
 metallic oxides, etc. 
 
 2. Carbonate of Potash (potassic carbonate). 
 — Ordinary carbonate {not bi-carbonate) of 
 potash. Since a mixture of the alkaline car- 
 bonates {i.e., carbonates of potash and soda), 
 is somewhat more fusible than either alone, 
 the use of this carbonate is advisable in cru- 
 cible assays, particularly of gold and silver 
 ores.- It should be ground to a fine powder 
 and kept from the air, as otherwise it would 
 rapidly absorb moisture. Its action is the 
 same as that of the bi-carbonate of soda. 
 
 J. Cyanide of Potash (potassic cyanide). — 
 The cyanide which is sold in cakes can be 
 used, after being pulverized, or, what is bet- 
 ter, the so-called granulated cyanide, which is 
 fine enough for all purposes. In case that in 
 form of cakes is on hand, it must be finely 
 
96 MANUAL OF ASSAYING. 
 
 pulverized, which ought to be done in the 
 open air, using an iron mortar, the top of 
 which is tied over and around with a towel. 
 Also it is well to breathe through a wet cloth 
 wrapped around the head across the nostrils, 
 for the cyanide is so poisonous that inhaling 
 the fine dust even is a dangerous practice. 
 Use the box sieve for sifting. Keep from the 
 air, as this salt absorbs moisture therefrom. 
 
 Employed in the lead assay. Action de- 
 sulphurizing and reducing (that is, taking 
 away the oxygen from metallic oxides and so 
 reducing them to the condition of metals ; it 
 is the reverse of oxidizing). 
 
 4. Borax Glass (sodic bi-borate). — The 
 most valuable flux the assayer possesses. He 
 employs it both for the crucible and scorifica- 
 tion processes for gold and silver ores, and 
 the crucible process for copper and lead ores. 
 It has a neutral action. The unfused borax, 
 in powder, is often used in the lead assay. 
 
 The ordinary borax of the shops contains 
 from 30 to 47 per cent of water of crystalliza- 
 
RE-AGENTS USED IN ASSAYING. 97 
 
 tion, which must be gotten rid of before the 
 borax is fit for use. Borax, on being strongly- 
 heated, swells very considerably while losing 
 this water, and then gradually sinks down into 
 a clear liquid, which, on cooling, becomes the 
 glass. 
 
 Take a large size sand crucible ("S" of 
 Battersea make) and carefully coat its interior 
 with either dry chalk or chalk wash. Place 
 this in a hot fire, and drop in small pieces 
 of borax, letting the swelling subside some- 
 what after each successive addition. It is 
 well not to allow the crucible to become more 
 than one-third full of the melted borax, as, in 
 spite of the chalk lining, it is liable to attack 
 the crucible and run through. 
 
 When thoroughly fused, appearing like wa- 
 ter, pour into a frying pan coated with chalk 
 or ruddle, and let cool. Powder in an iron 
 mortar and sift through a 40-mesh sieve. That 
 which goes through had best be reserved for 
 crucible mixtures ; the moderately coarse re- 
 maining on the sieve will do for scorifications. 
 
98 MANUAL OF ASSAYING. 
 
 A strong iron coffee-mill with teeth or jaws 
 close together, will crush borax glass very 
 finely, and in much less time than it can be 
 done with mortar and pestle. 
 
 An iron crucible can be employed in place 
 of the sand one. It will color the borax 
 somewhat, which, however, does no damage. 
 
 5. Flour. — Wheat flour is serviceable in the 
 lead assay, its action being reducing. But it 
 is more commonly employed together with bi- 
 carbonate of soda, forming what is known as 
 
 6. Black Fhix Stibstitute. — A mixture of 
 ten parts bi-carbonate of soda and three of 
 flour. It can be used to great advantage in 
 the crucible assays of all of our four metals. 
 
 7. Argol (crude bi-tartrate of potash; when 
 pure called cream of tartar or hydro-potassic 
 tartrate). — This is a good reducing agent, 
 and is much used in the lead assay, and in 
 crucible charges for gold, silver and copper 
 ores. Whether employed as argol or cream 
 of tartar, its reducing power should be deter- 
 mined. (See page 121). 
 
RE-AGENTS USED IN ASSAYING. 
 
 99 
 
 8. Common Salt (sodic chloride). — Ordi- 
 nary table salt. Very useful in every cruci- 
 ble assay. It serves somewhat as a protect- 
 ing cover, and as a wash, bringing down from 
 the sides of the crucible adhering metals or 
 fluxes. If moist, place in frying pan and 
 heat till dry, then crush free from lumps. 
 
 g. Carbonate of Ar^tmonia (ammonic car- 
 bonate). — Of very little importance, save> to 
 assist in the roasting of certain ores. It ex- 
 erts a desulphurizing action. To be employed 
 as a fine powder. 
 
 10. Nitre or Saltpetre (potassic nitrate). — 
 Ordinary saltpetre of commerce.- Is a basic 
 flux and oxidizing agent, and is used in the 
 crucible assays of gold, silver and lead ores. 
 Pulverize finely and keep dry. Determine 
 oxidizing power as shown on page 122. 
 
 11. Wood Charcoal (carbon, more or less 
 impure). — Very valuable on account of its 
 reducing and desulphurizing properties. It 
 exercises the latter action when employed in 
 the roasting of antimonial and arsenical gold 
 
lOO MANUAL OF ASSAYING. 
 
 and silver ores. Let it be in a fine condition, 
 keep dry, and determine reducing power in 
 same manner as for argol or cream of tartar. 
 (See page 122.) One gramme of ordinary- 
 wood charcoal will reduce from 28 to nearly 
 32 grammes of metallic lead from litharge, 
 according to the purity of the charcoal. In 
 the scorification assay of certain ores (arsen- 
 ical, antimonial, etc.), charcoal exerts a 
 beneficial action in breaking up the crust 
 which sometimes forms on the surface of the 
 charge. A few pieces of roughly pulverized 
 charcoal introduced into the matrass in part- 
 ing gold bullion, excite local action and so pre- 
 vent the bumping of the nitric acid solution. 
 
 There are quite a number of substances con- 
 taining carbon in varying proportions, which, 
 for the sake of their reducing action, might 
 be used as substitutes for cream of tartar and 
 charcoal, but not one of them is so effective 
 as either of the two mentioned, and since the 
 latter are so easily obtained, I refrain from 
 even listing the others. 
 
RE-AGENTS USED IN ASSAYING. lOI 
 
 12. Silica (silicic di-oxide). — This is a valu- 
 able acid flux, that is, it is to be used as a flux 
 for ores which are basic in character (as calc 
 spar, dolomite, barytes, fluor spar, etc.), also 
 for ores containing large quantities of iron 
 oxides and carbonates and with little or no 
 silica. It is required for the assays of cer- 
 tain ores of gold and silver in both the cruci- 
 ble and scorification processes, as will be 
 shown. The best form in which to use it is 
 as precipitated silica (sold very cheaply), 
 since it is then in a very fine state of division 
 suitable for intimate mixture with ores and 
 fluxes. It should be perfectly dry. 
 
 As substitutes, in emergencies, fine, clean, 
 dry sand can be used, and some kinds of 
 glass (which are silicates of soda or potash, 
 with lime, lead, etc.). Lime glass is to be 
 preferred, but on no account is lead glass, or 
 any containing arsenical compounds or easily 
 reducible metallic oxides, to be employed. 
 Common window glass and ordinary bottle 
 glass, broken finely, will serve, and will be 
 
I02 MANUAL OF ASSAYING. 
 
 found to be free from objectionable metallic 
 ingredients. 
 
 There is no advantage gained in using 
 these substitutes, since the precipitated silica 
 answers admirably, only it is well to know 
 what to make use of, in case supplies run out. 
 
 ij. Lead. — In thin sheets, called lead-foil, 
 this metal is occasionally necessary for cupel- 
 lations, as described under the assaying of 
 gold and silver, and in the gold bullion assay. 
 It should be tested for silver. (See page 120). 
 
 In the granulated form (when it is some- 
 times called test lead) lead is as invaluable 
 as borax glass for the scorification assay. It 
 can be purchased of varying degrees of fine- 
 ness and purity, or it can be made from bar 
 lead by the assayer himself, as here directed. 
 
 Melt pieces of the bar lead in any conven- 
 ient vessel (odd sizes of sand crucibles, for 
 instance), and when it is of a temperature 
 just hot enough to char a splinter of wood, 
 pour into a compactly-joined cigar box with- 
 out a cover, or a strong starch box. Imme- 
 
RE-AGENTS USED IN ASSAYING. 103 
 
 diately give a gentle rotary motion ta the 
 contents of the box, till the lead begins to 
 thicken, and emits a slight creaking noise, 
 when the motion is to be increased to a final 
 vigorous shaking from side to side. A min- 
 ute or two of this latter, and the thing is 
 done. Sift through a 20-mesh or an ordinary 
 flour sieve, and remelt that which remains on 
 the sieve. When the entire batch has been 
 thus granulated, assay for silver, following 
 the directions on page 118. 
 
 14. Litharge (plumbic mon-oxide, yellow 
 oxide of lead). — Employed mainly for the 
 crucible assays of gold and silver ores. It 
 should be dry, and free from any considera- 
 ble amount of red oxide of lead, as this 
 causes oxidation of silver, and consequently 
 loss. Mitchell says: " Ordinary litharge can 
 be easily freed from this oxide by fusing it 
 and pouring it into a cold ingot mould, then 
 pulverizing, and carefully keeping it from 
 contact with air, as it readily absorbs oxygen, 
 and if it be allowed to cool in the atmos- 
 
I04 
 
 MANUAL OF ASS A YING. 
 
 phere, it will nearly' all be converted into the 
 red oxide." 
 
 Litharge can quite easily be procured free 
 from large quantity of red oxide, and if it is 
 kept in a tightly-stoppered bottle or tin can 
 with closely fitting cover, there is little dan- 
 ger of conversion to this oxide. 
 
 It is used to furnish metallic lead that 
 serves as a solvent for the precious metals in 
 the ore. When in the melted state it has 
 the power of giving up its oxygen to almost 
 all the metals (save gold, silver and those of 
 the platinum group), converting them into 
 oxides, and since these are generally ex- 
 tremely fusible, they go into the slag. Thus 
 we are able to separate gold and silver from 
 any baser metals they may be combined or 
 associated with. 
 
 Litharge is a very powerful desulphurizing 
 agent (see Mitchell, pp. i8i to 187), and also 
 serves as a metallic ,flux. 
 
 It may safely be stated that all litharge 
 contains silver to a greater or less degree. 
 
RE-AGENTS USED IN ASSAYING. 105 
 
 It may be, and generally is, in small quantity, 
 but it is absolutely necessary to determine 
 the amount, and to allow for it in the calcula- 
 tion of silver in any ore tested. 
 
 For the determination of this, see page 1 16. 
 
 White lead (ceruse, plumbic carbonate, or 
 carbonate of lead), and sugar of lead (plumbic 
 acetate), can be made use of as substitutes 
 for litharge, but they do not act quite so well. 
 
 75. Iron. — A good desulphurizing agent, 
 and as such is much employed in the assay of 
 galena or sulphide of lead. Wire of j!j^ inch 
 diameter, and eight-penny nails are the cor- 
 rect sizes. Iron filings can sometimes be 
 used. 
 
 16. Silver. — Can be bought as very thin 
 foil. It is quite often needed in inquartation 
 (which see). It should be tested for gold by 
 dissolving \ gramme in pure nitric acid. After 
 the solution is complete, there should be no 
 black specks (gold), no matter how small, in 
 the liquid. There is generally no difficulty in 
 procuring silver perfectly free from gold. 
 
I06 MAX UAL OF ASSAYING. 
 
 WET RE-AGENTS FOR ASSAYING. 
 
 The wet re-agents necessary in the assaying 
 of our chosen four metals, are but two in 
 number ; distilled water and nitric acid. 
 
 I. Distilled Water. — It is not worth the 
 while to give directions for the preparation of 
 this liquid ; it is simply to boil water and con- 
 dense the steam by those means most con- 
 venient to the assayer. It can be purchased 
 in the large cities, but is quite expensive. 
 Pure rain water is a very fair substitute. 
 The main point in any case, is to see that it 
 contains no chlorine (indicating generally, 
 chloride of sodium or common salt). Test 
 the water for this element, by acidulating a 
 clear sample with pure nitric acid, and adding a 
 drop or two of nitrate of silver solution (made 
 by dissolving one part of the dry nitrate of 
 silver in twenty parts of distilled water). The 
 water should remain perfectly clear, that is, 
 there should not be in it the slightest cloudi- 
 ness or turbidity. If it does show this, reject, 
 and prepare or secure a fresh supply. 
 
RE-AGENTS USED IN ASSAYING. 107 
 
 2. Niirtc Acid (hydric nitrate). — Indispens- 
 able for parting, i.e., the separation of silver 
 and gold by dissolving out the former. It can 
 be procured perfectly pure, but should always 
 be tested for chlorine, in same manner as for 
 distilled water. Should it contain this objec- 
 tionable ingredient, it can be removed by 
 adding one drop of nitrate of silver solution 
 and letting the acid stand in the light till 'the 
 purple-black precipitate of chloride of silver 
 settles to the bottom of the bottle. Then add 
 a second drop, and let remain undisturbed as 
 before. Continue these successive single drop 
 additions until finally the last drop ceases to 
 form any precipitate or milkiness in the acid. 
 Draw off the clear acid and keep tightly stop- 
 pered. There are two reasons why chlorine 
 should not be found in the nitric acid. First, 
 it will tend to throw down, as silver chloride, 
 the silver dissolved out of a bead by the 
 nitric acid in the process of parting. Secondly, 
 it indicates the presence of hydrochloric acid, 
 and this acid forms aqua regia with the nitric 
 
I08 MANUAL OF ASSAYING. 
 
 acid, which could easily dissolve the very 
 small amounts of gold sometimes left after 
 parting. 
 
 RE-AGENTS FOR ANALYSIS. 
 
 The other re-agents, wet and dry, used in 
 the qualitative tests, analyses, and special pro- 
 cesses, are the following : 
 
 Alcohol. — Wanted in the copper analysis 
 and perhaps as fuel for a lamp. Use common 
 alcohol. 
 
 Ammonia Waler (^ammomc hydrate, caustic 
 ammonia, aqua ammonia). — If very strong, di- 
 lute one part with two parts of distilled water. 
 
 Bi-chromate of Potash (potassic di-chro- 
 mate). — Used in the volumetric determination 
 of iron. Should be procured pure. 
 
 Black Oxide of Manganese (manganese di- 
 oxide). — Necessary to aid in the preparation 
 of chlorine gas. Does not need to be per- 
 fectly pure. 
 
 Caustic Potash (potassic hydrate). — One 
 part of common stick potash, dissolved in ten 
 parts of water. 
 
RE-AGENTS USED IN ASSA YING. 109 
 
 Chloride of Barium (baric chloride, muri- 
 ate of baryta). — One part of the pure salt 
 dissolved in ten parts of distilled water. 
 
 Citrate of Ammonium (amnionic citrate). — 
 Dissolve one part of the salt in ten parts of 
 distilled water. 
 
 Ferrocyanide of Potassium, (potassic ferrocy- 
 anide, yellow prussiate of potash). — One part 
 of the pure salt, dissolved in twelve parts of 
 distilled water. 
 
 Hydrochloric Acid (muriatic acid). — To be 
 pure. One bottle may be of the concentrated, 
 a second of a mixture of one part acid with 
 four parts of distilled water. 
 
 Hyposulphite of Sodium, (sodic hyposul- 
 phite). — Employed in both the volumetric 
 determination of manganese and chlorination 
 test for silver, which see. 
 
 Iodide of Potash (potassic iodide). — Wanted 
 in the volumetric determination of manganese 
 and as a test re-agent for lead. When used for 
 the latter purpose. It may be either in the solid 
 form, or in solution in water — one part in ten. 
 
no MANUAL OF ASSAYING. 
 
 Lime Water (calcic hydroxide). — Place a 
 very little slaked lime in a bottle ; fill with 
 water and shake. Keep tightly corked, and, 
 when wanted, draw off the clear liquid with- 
 out disturbing the sediment. 
 
 Mercuric Chloride (corrosive sublimate). — 
 Needed only for the volumetric determination 
 of iron, which see. 
 
 Metallic Copper. — Wire for battery purposes, 
 and sheet for amalgamation test in panning 
 (which see), will be needed. 
 
 Metallic Mercury. — Some that is impure can 
 be employed to amalgamate the zinc plates of 
 a battery, and some free from gold and silver 
 will be wanted in the various amalgamation 
 tests. 
 
 Metallic Zinc. — In plates, forming a part of 
 a battery. As a re-agent, zinc in pencils, or 
 granulated, will be needed /?^r^. 
 
 Nitrate of Silver (argentic nitrate, lunar 
 caustic). — See testing of distilled water for 
 chlorine. 
 
 Nitric Acid. — A bottle of pure and concen- 
 
RE-AGENTS USED IN ASSAYING. Ill 
 
 trated acid, and one of the common commer- 
 cial (concentrated) for battery, should be on 
 hand. 
 
 Stannous Chloride (proto-chloride of tin, 
 "tin salts"). — For the volumetric determina- 
 tion of iron. 
 
 Sulphate of Iron (ferrous sulphate, green 
 vitriol, copperas). — In solution in water (of 
 no particular strength) it is used to precipi- 
 tate gold from its solution as a chloride, after 
 the chlorination assay. 
 
 Sulphide of Iron (ferrous sulphide, sulphuret 
 of iron). — See next paragraph but one. Can 
 be purchased, or made by holding roll sulphur 
 against a bar of red-hot iron. 
 
 Sulphocyanide of Potassium (potassic sul- 
 phocyanide). — One part of the pure salt dis- 
 solved in ten parts of distilled water. 
 
 Sulphuretted Hydrogen Water (hydrogen 
 sulphide gas dissolved in water). — Very use- 
 ful in qualitative analysis. To generate it, fit 
 together a simple piece of apparatus similar 
 to fig. 69. The larger bottle, which may be 
 
I I 2 MANUAL OF ASS A YING. 
 
 of any capacity above six ounces, is provided 
 with a doubly-perforated cork, through one 
 hole of which passes a straight glass tube to 
 nearly the bottom of the bottle, and terminat- 
 ing in a funnel. Through the other hole a 
 second tube passes a little way into the larger 
 bottle, and bending twice at right angles, goes 
 through the cork of the smaller bottle to 
 nearly its bottom. A third tube leaves this 
 smaller bottle and connects by a bit of rub- 
 ber tubing with a fourth tube dipping into 
 the receiving bottle containing distilled water. 
 Place an ounce or two of sulphide of iron 
 broken in small pieces in the bottom of the 
 large bottle and fill half-way up with ordi- 
 nary water. The small bottle is to be half- 
 filled with distilled water to wash the gas. 
 Pour some common sulphuric acid into the 
 funnel-tube, when the gas will at once be 
 given off. To ascertain when the water in 
 the re-agent bottle is saturated, hold the 
 thumb tightly over its mouth and shake. On 
 releasing the pressure a little the thumb will 
 
RE-AGENTS USED IN ASSA YING. 
 
 "3 
 
 be held down if the water is not saturated, 
 but will be forced up, if the contrary is true. 
 A little glycerine put in the re-agent bottle 
 will help to retain the gas in solution. 
 
 Fig. 69. 
 
 Sulphuric Acid (oil of vitriol). — A bottle of 
 pure" and another of common, both concen- 
 trated. If dilute acid is wanted, mix, in a 
 beaker, one part of the acid with five of dis- 
 tilled water. 
 
 Chloride of Calcium (calcic chloride). — The 
 dry, fused lumps, used to keep moisture away 
 from fine scales. Need not be chemically pure. 
 
 Bone-ash. — For making cupels, which see. 
 It is best to use a good quality. 
 
114 MANUAL OF ASSAYING. 
 
 Ruddle (ferric sesqui-oxide, red oxide of 
 iron, hematite). — A lump for marking cupels 
 and scorifiers, and a paint (prepared by put- 
 ting an ounce or two of the fine powder with 
 water in a bottle and shaking) for marking 
 crucibles, coating frying-pan, etc., are wanted. 
 
 Chalk and Chalk Wash. — Ordinary chalk, 
 to be used dry, and the same finely ground 
 and rubbed up with water, for coating cru- 
 cibles, etc. 
 
 Clay Lute.-, — Fire-clay and sand, with solu- 
 tion of common borax in water to bind them 
 together. Horse and cow-hair may also be 
 mixed with them. 
 
CHAPTER III. 
 
 TESTING OF RE-AGENTS; PRELIMINARY 
 WORK, 
 
 Before proceeding to make the regular 
 assays, the student will find it expedient to 
 examine his re-agents, either to ascertain the 
 presence or absence of silver (and in the 
 former case, to determine its quantity), or to 
 learn their various strengths, as shown in 
 their reducing or oxidizing powers. 
 
 The following six divisions include all the 
 requisite tests of re-agents, together with one 
 for a special class of ores: 
 
 I. Testing of Litharge for Silver. 
 II. Testing of Granulated Lead for Sil- 
 ver. 
 
 III. Testing of Sheet Lead for Silver. 
 
 IV. Determination of the Reducing Pow- 
 
 ers of Reducing Agents. 
 V. Determination of the Oxidizing Pow- 
 er of Nitre (Nitrate of Potash). 
 
I 1 6 MANUAL OF A SSA YING. 
 
 VI. Determination of the Reducing Pow- 
 ers of Certain Ores. 
 
 I. TESTING OF LITHARGE FOR SILVER. 
 
 As stated in the chapter on re-agents, 
 almost all litharge contains silver, generally 
 as a small amount. However minute this 
 may be, we must know exactly what it is, and 
 allow for it in calculating the value of an ore. 
 
 This we do by the crucible process, in the 
 same manner as we should run an ore. (See 
 Part II, Chapter I.) 
 
 Mix very thoroughly the particular lot of 
 litharge to be examined, and sample as usual. 
 
 Make the charge 
 
 Bi-carbonate of soda 4 A. T. 
 
 Carbonate of potash \ 
 
 Litharge 4 
 
 Charcoal 0.7 gramme 
 
 Salt cover. 
 Mix everthing well, and brush into an "S" 
 Battersea crucible Or its equivalent (4f inches 
 by 4|- wide). 
 
 Have the fire quite hot, and heat crucible 
 
TESTING OF RE-AGENTS. W] 
 
 till contents ar.e in quiet fusion, which will be 
 in from twenty-five to thirty-five minutes. 
 Take out, let cool, break, and hammer button 
 into shape. 
 
 If the button is too large for any cupel 
 reduce by scorifying, then cupel. (See "Scori- 
 fication and Cupellation," Part II, Chapter I.) 
 
 Weigh the resulting silver button, and 
 divide its weight by four ; the quotient will 
 be the number of milligrammes (and frac- 
 tions) of silver per assay ton that the litharge 
 contains. 
 
 Several lots of litharge I have tested car- 
 ried 0.75 (f) of a milligramme per assay ton, 
 and as the amount of litharge required for 
 an ordinary crucible charge is 2 assay tons, 
 the amount of silver to deduct from a silver 
 bead obtained from an actual assay, would be 
 1.5 milligrammes. 
 
 -The above amount, equivalent to i^ ounces 
 per ton of 2,000 pounds, is of course very 
 small, and, in the calculation of the value of 
 an ore running say 100 oz. and upward, need 
 
I 1 8 MANUAL OF ASSA YING. 
 
 not be deducted from the weight of the silver 
 bead, since the loss of silver by absorption 
 and volatilization from such a bead while 
 cupelling, would more than counterbalance it. 
 But it is very important that it should be 
 deducted in the case of a poor ore, and 
 especially when there is a question as to the 
 presence or absence of silver in any ore. 
 
 For the sake of practice, it will be well for 
 the student to perform this crucible assay of 
 litharge three or four times. 
 
 II. TESTING OF GRANULATED LEAD FOR SILVER. 
 
 As in the case of litharge, all granulated 
 lead must have its amount of silver deter- 
 mined, which is done by the scorification 
 process. 
 
 Mix and sample as usual. Weigh very 
 carefully 2 A. T. of the lead, and pour into a 
 2| inch scorifier, and deposit on the top a 
 piece of borax glass about the size of the 
 head of a pin. 
 
 Scorify and cupel as shown in the next 
 
TESTING OF RE-AGENTS. II9 
 
 chapter^ and weigh resulting bead. The 
 weight of the silver bead, divided by two, will 
 give the number of milligrammes or frac- 
 tions7 that one assay ton of the lead contains, 
 which I have found to vary from -^-^ milli- 
 gramme to 1.2 milligrammes. 
 
 Make a table of the amounts of silver con- 
 tained in fractions and multiples of one assay 
 ton, and post it in some convenient place for 
 reference. I give an example of one particu- 
 lar lot: 
 
 0.50 A. T. contains 0.40 milligramme silver. 
 
 i.oo " " 0.80 
 
 1.50 " " 1.20 " " 
 
 2.00 " " 1.60 
 
 If Other weights of lead are used, calculate 
 accordingly. 
 
 Deduct silver, in proportion due to the 
 amount of lead used, from beads coming 
 from ores ranging less than lOO ounces ; 
 above that disregard it, as with litharge. As 
 with litharge make several runnings of the 
 lot of lead. 
 
I20 MANUAL OF ASSAYING. 
 
 III. TESTING OF SHEET LEAD FOR SILVER. 
 
 Sheet lead can generally be purchased re- 
 markably free from silver, and as it is seldom 
 that a piece of more than ten or twelve 
 grammes in weight is required, the quantity 
 of silver such a piece will contain, will be 
 exceedingly small. Moreover, its chief use 
 being to enwrap gold and silver beads for re- 
 cupellation, this amount of added silver is too 
 minute to counterbalance the loss of silver by 
 volatilization and absorption. Sheet lead is 
 sometimes employed to aid in cupelling gold 
 beads that have been inquarted, and here a 
 loss or addition of silver is not important. 
 
 But should the lead-foil be suspected of 
 carrying any quantity of silver, its exact 
 amount can be determined by cutting off from 
 various parts of the foil, and in small shreds, 
 two or four assay tons, which are to be scori- 
 fied and cupelled as usual. 
 
TESTING OF RE-AGENTS. 121 
 
 IV. DETERMINATION OF THE REDUCING POWERS 
 OF REDUCING AGENTS. 
 
 /. Argol (p. 98). — Weigh out the follow- 
 ing charge : 
 
 Bi-carbonate of soda i A. T. 
 
 Carbonate of potash \ " 
 
 Litharge i " 
 
 Argol 2 grammes 
 
 Salt cover. 
 Put into a small crucible (size " V " of Bat- 
 tersea), place in a hot fire, cover, remove 
 when thoroughly fused, cool, detach button 
 from slag, weigh, following the directions 
 given for the crucible assays of gold and 
 silver. 
 
 The result, divided by two, will give the 
 number of grammes of metallic lead that one 
 gramme of argol is able to reduce from 
 litharge. It ranges around 8.5 grammes. 
 
 2. Cream of Tartar, or bi-tartrate of pot- 
 ash (p. 98). — Same charge as above, excepting 
 that the two grammes of argol are to be re- 
 placed by three grammes of the tartar. One 
 
122 MANUAL OF ASSAYING. 
 
 gramme of pure tartaric acid will reduce 6 
 grammes of lead, and the same amount of 
 ordinary cream of tartar will reduce 6.4 
 grammes of lead. 
 J. Charcoal (j). 99). — Make up this charge: 
 
 Bi-carbonate of soda 2 A. T. 
 
 Carbonate of potash \ " 
 
 Litharge 2 " 
 
 Charcoal i gramme 
 
 Salt cover. 
 Use an " S " crucible, and treat as before. 
 As previously stated, the reducing power of 
 one gramme of charcoal varies between 28 
 and 32 grammes of lead. 
 
 V. DETERMINATION OF THE OXIDIZING POWER 
 OF NITRE (nitrate OF POTASh). 
 
 Determine the oxidizing power of the fine, 
 dry salt (p. 99), by the following charge (Rick- 
 etts' modified) : 
 
 Bi-carbonate of soda 2 A. T. 
 
 Carbonate of potash i " 
 
 Litharge 2 " 
 
 Charcoal i gramme 
 
 Nitre 3 grammes 
 
 Salt cover. 
 
PRELIMINARY WORK. I 23 
 
 Use an " S " crucible and treat as in the 
 previous crucible operations. The difference 
 between the weight of the lead button ob- 
 tained and that found in the assay of the 
 charcoal, divided by three, will give the oxi- 
 dizing power of the nitre, per gramme. It is 
 about I gramme. 
 
 VI. DETERMINATIOf OF THE REDUCING POWERS 
 OF CERTAIN ORES. 
 
 Certain ores exert a reducing action upon 
 litharge, which action is injurious only in that 
 it increases the weights of the lead buttons 
 obtained by crucible assays, thus necessitating 
 their being scorified down to a size suitable 
 for cupellation. 
 
 Antimony, arsenic, sulphur and zinc are the 
 elements which effect the reduction, and in 
 case they are present in large quantities, they 
 can be removed in the manner indicated under 
 "Roasting" in Part II, Chapter I. 
 
 It is not often necessary to determine the 
 reducing powers of such ores, especially with 
 
124 MANUAL OF ASSAYING. 
 
 the advanced assayer, for he learns by experi- 
 ence, by a single glance at a specimen, how 
 to allow for them in his assay, by noting the 
 comparative amounts of the four undesirable 
 constituents. 
 
 When, however, such information is wanted, 
 prepare the following charge : 
 
 Bi-carbonate of soda i A. T. 
 
 Carbonate of potash \ " 
 
 Litharge i " 
 
 Ore tV " 
 
 Salt cover. 
 (See Ricketts, pp. 66-67.) Fuse in as short 
 a time as possible, cool, break crucible, etc., 
 etc. One of three results will happen. The 
 -jig- A. T. ore employed will produce : 
 
 1. No lead, or less than three grammes. 
 
 2. Three grammes. 
 
 3. More than three grammes. 
 
 To illustrate by an example : Imagine that 
 for the actual assay i assay ton of the ore is 
 to be used, this quantity being the usual 
 charge for a crucible running. Should the -^ 
 A. T. ore reduce 1.2 grammes of lead, then i 
 
PRELIMINARY WORK. I 25 
 
 A. T. would, of course, reduce 12 grammes. 
 This is indeed a very good weight to cupel, 
 but if we wanted the button a little heavier, 
 say 16 grammes, we should be obliged to add 
 argol, cream of tartar, charcoal or other re- 
 ducing agent to make up the balance of 4 
 grammes. Assuming i gramme of charcoal 
 to reduce 28 grammes of lead, then ^ of a 
 gramme or about 150 milligrammes would be 
 . an amount that would produce the 4 grammes 
 very nearly. 
 
 In the second case, if -^ A. T. ore reduced 
 3 grammes,, i A. T. would reduce 30 grammes, 
 a little too heavy a weight, which could be 
 obviated by using only \ A. T. of the ore for 
 assay, producing a button of 15 grammes, or 
 oxidizing as in the third supposition. 
 
 " If the reducing power corresponds to the 
 third case, divide the excess of lead by the 
 .oxidizing power of nitre ; the quotient will 
 show how much nitre is needed." 
 
 Examine the slag, to correct or to duplicate 
 it in the actual running of the ore. 
 
PART II. 
 ASSAYING. 
 
PART II. 
 ASSAYING. 
 
 CHAPTER I. 
 GOLD AND SILVER ORES. 
 
 Occurrence. — Gold is found in large quan- 
 tities in the native state, designated by the 
 various names of free gold, flour, leaf, wire 
 and nugget gold. The minerals which most 
 frequently carry gold are oxide of iron, pyrites 
 of iron and copper (known as auriferous sul- 
 phurets), arsenopyrite, and tellurium ores ; of 
 these, the most abundant are the first two. 
 
 Minerals which less frequently are gold- 
 bearing, are galena, blende, gray copper and 
 "carbonate ores." 
 
130 MANUAL OF ASSAYING. 
 
 For a classification of silver ores I quote 
 from Kustel's " Roasting of Gold and Silver 
 Ores " : 
 
 " IMPORTANT SILVER ORES. 
 
 The most important silver ores are those 
 found in such quantities as to be an object of 
 metallurgical operations. The principal min- 
 erals of this kind are the following : 
 
 A. Stiver ores with unvariable amount of 
 silver. - — a. Sulphuret of silver, or silver 
 glance, with 87 per cent of silver. It is of 
 common occurrence. b. Brittle silver ore 
 {stephanite^, or sulphuret of silver and anti- 
 mony. This mineral contains 68 per cent of 
 silver, and is quite common, c. Polybasite, 
 sulphuret of silver, antimony and some ar- 
 senic, with 75 per cent of silver, d. Ruby 
 silver. The dark red silver ore, or antimonial 
 variety, with 59 per cent, and the light red 
 silver ore, or arsenical variety, with 65 per 
 cent of silver, are valuable minerals. e. 
 Miargyrite, sulphuret of silver and antimony ; 
 36.5 per cent of silver, f. Horn silver, or 
 
GOLD AND SILVER ORES. 
 
 131 
 
 chloride of silver, with 75 per cent of silver. 
 g. Iodic and bromic silver of yellow and green 
 colors. 
 
 B. Argentiferous ores with variable amount 
 of silver. — a. Stromeyerite, or silver copper 
 glance, a sulphuret of silver and copper con- 
 taining up to 53 per cent of silver, b. Stete- 
 feldite, with 25 per cent of silver, is an oxide 
 ore. c. Silverfahlore, argentiferous gray cop- 
 per ore. It contains silver in very variable 
 proportions up to 31 per cent. This ore is 
 quite common, and for this reason is impor- 
 tant. It is also one of the most rebellious 
 ores, containing copper, antimony, arsenic, 
 sulphur, lead, Iron, zinc, and sometimes gold 
 and quicksilver, d. Chloride ores (so-called), 
 mostly decomposed ores, generally of an 
 earthy appearance and different colors. They 
 contain more or less finely divided chloride of 
 silver. 
 
 C. — a. Argentiferous lead ores, galena, or 
 sulphuret of lead, lead glance. Generally, this 
 is not rich in silver, containing from $20 to 
 
132 MANUAL OF ASSAYING. 
 
 $60 per ton. Specimens assay sometimes as 
 high as $300.* b. Cerussite, carbonate of 
 lead. If pure, without admixture of copper 
 and other carbonates, it is poor in silver in 
 most cases, c. Argentiferous zinc blende, sul- 
 phuret of zinc. Pure zinc blende contains 
 usually only traces of silver ; often, however, 
 it assays well, even up to $400 per ton. d. 
 Argentiferous pyrites. Copper and iron py- 
 rites are poor in silver, but often auriferous. 
 
 There are, besides, numerous classes of 
 decomposed silver ores, generally of earthy 
 nature ; also, half decomposed ores which 
 have lost their metallic glance, having a black 
 or bluish-black color, and being generally 
 cupriferous." f ^ 
 
 Assay. — We can best consider the system- 
 atic fire treatment of gold and silver ores, by 
 dividing it into a series of operations, and 
 taking each in turn and in detail. 
 
 * I have found them as high as $1,500 per ton. (W. L. B.) 
 f See appendix for extended lists of the minerals of or contain- 
 ing gold and silver. 
 
GOLD AND SILVER ORES. 1 33 
 
 The three main divisions are : 
 
 I. Preparation of the sample. 
 
 II. Scorification process. 
 
 III. Crucible process. 
 
 I. PREPARATION OF THE SAMPLE. 
 
 The first thing to be done in the treatment 
 of an ore, whether it is to be assayed for gold, 
 silver, copper, lead, or any other metal, is to 
 place it, that is, to label it. This is best ac- 
 complished by giving to it a running number, 
 never to be repeated. By adopting this sys- 
 tem of numbering all samples, any danger of 
 confusing specimens from various mines or 
 parts of the same mine or vein, is entirely 
 gotten rid of. Have a notebook at hand, 
 and, in it, under the number, write such items 
 as may be necessary or useful, as the date 
 when sample was received, name of person 
 sending it, character of the ore, nature of the 
 charge, weights employed, calculations, etc. 
 To pieces of the ore which are to remain 
 whole, affix gummed labels, bearing the same 
 
134 MANUAL OF ASSAYING. 
 
 number. To preserve the final pulverized 
 samples, bottles of about four ounces capacity, 
 cork-stoppered, and similarly labelled, can be 
 employed, or what is even better, pasteboard 
 boxes in size about 5^ inches long by 3^ 
 inches wide and 2 inches high, will be found 
 to be very serviceable. They can be written 
 on, thus requiring no labels. 
 
 The next step is to secure an average sample 
 for assay, and its importance cannot be over- 
 rated. An ore is by no means of uniform, 
 character, being, in general, made up 'of the 
 gangue or valueless portion of the ore, through 
 which are scattered the valuable minerals. 
 Therefore, unless the sample finally chosen 
 for assay represents an average of the entire 
 lot, being a mixture in the same proportions, 
 of the richest, the medium and the poorest 
 portions, as in the original ore, the assay itself 
 is worthless, no matter how carefully it may 
 have been performed.* 
 
 *In this connection", I would refer the student to an 3,rticle 
 "On the Commercial Sampling of Minerals," by Mr. L. S. Austin, 
 of Salt Lake City, Utah, which appeared in the "Engineering and 
 Mining Journal" (July 22, Aug. 5, Aug. 26, and Sept. 16, 1882). 
 
GOLD AND SILVER ORES. 1 35 
 
 To illustrate the averaging, take a quantity 
 of ore weighing fifty pounds, which may be as 
 a single lump, or, better, the result of the 
 selection of samples across a section of the 
 vein. In order to get a fair average, it is not 
 necessary to operate on a larger quantity than 
 this amount, for above it, should come in, as 
 a more practical test, the mill-run. 
 
 With a heavy sledge-hammer, break up the 
 entire mass into pieces of about the size of a 
 hickory-hut, transfer to a large sheet of heavy 
 brown or manilla paper, then, with a large iron 
 or steel spatula, thoroughly mix, by turning 
 over and over and by stirring in together with 
 the dust, the finer and coarser particles, till 
 satisfied that the whole is a homogeneous 
 mixture. 
 
 (At this stage of the operation, it is a good 
 plan to reserve a characteristic lump or a few 
 pieces, from an examination of which the 
 nature of the ore may be determined, and 
 process of treatment decided upon.) 
 
 Now divide in halves, and break up still 
 
136 MANUAL OF ASSAYING. 
 
 finer (to the size of a hazel-nut or less) the 
 half selected. Mix again and halve as before. 
 Continue the crushing, mixing and halving 
 until about one pound has finally been 
 sampled down. 
 
 When the ore to be assayed is less than 
 fifty pounds, ranging down to a pound or two, 
 it can be broken still smaller in the successive 
 steps, and when it is but a few ounces in 
 weight, the whole of it should be crushed and 
 pulverized, as directed. Wet or damp ores 
 and pulps should be dried before pulverizing. 
 
 The student must exercise his judgment in 
 a measure, with regard to the sampling of an 
 ore, simply remembering that the object, as 
 before stated, is to obtain a final product 
 which shall be an exact counterpart, in rela- 
 tive proportions, of the metals and gangue of 
 the original ore. 
 
 Instead of halving, the broken ore may be 
 taken up on a sampling shovel, and thrown 
 on a tin or copper sampler, making it a rule 
 to reject either all that which goes between 
 
GOLD AND SILVER ORES. 1 37 
 
 the prongs or ribs, or that which remains up- 
 on them. These two articles are convenient, 
 but not necessary. 
 
 The third step i^ to pulverize the sample 
 finally obtained, which may be done very sim- 
 ply though somewhat laboriously (depending, 
 considerably upon the nature of the ore), by 
 means of an iron mortar and pestle. A towel 
 wrapped loosely around the pestle and across 
 the top of the mortar will prevent loss due to 
 flying particles. 
 
 Sift through a sieve of eighty or ninety or 
 even of one hundred meshes, since the finer 
 the powder, the more quickly will it be acted 
 upon in the furnace. Do the sifting over a 
 piece of brown paper, and be sure that all the 
 sample passes through the sieve, for the few 
 minute particles or scales, that might remain 
 on the sieve and be hastily thrown away, could 
 be of sufficient value to vitiate the assay. 
 (See in appendix, "Assaying of Ores Con- 
 taining Free Gold or Free Silver".) 
 
 Mix again the fine powder, and with a large 
 
138 MANUAL OF ASSAYING. 
 
 brush transfer to the properly marked box or 
 bottle, when the sample is ready for assay. 
 
 When very many assays have to be per- 
 formed daily, the rubbing-plate and rub- 
 bers will be found so very convenient and so 
 time-and-labor-saving, that they will become 
 almost necessities. (See pp. 21-24 for descrip- 
 tion and method of using.) 
 
 In place of the sheets of brown paper al- 
 ready mentioned, and which quickly become 
 soiled and full of holes, the zinc sifting-pans 
 (p. 26, fig. 7) can be used to advantage. 
 
 To guard against loss of dust, the tin box- 
 sieve (p. 26) is recommended. 
 
 Having brought to the requisite degree of 
 fineness the sample of ore to be assayed, the 
 next thing, to be done is to select its method 
 of treatment. 
 
 There are two methods of assaying gold 
 and silver ores, the scorification and the cru- 
 cible. 
 
 The process to be chosen depends chiefly 
 
GOLD AND SILVER ORES. 1 39 
 
 on the nature of the ore. In general., we may- 
 say the scorification process is better adapted 
 for all silver ores, and for rich gold ores (in- 
 cluding telluride ores of any degree of rich- 
 ness). 
 
 The crucible process serves better for low 
 grade gold ores. The advantage of this pro- 
 cess lies mainly in the fact that it enables us 
 to operate upon a larger quantity of ore; oth- 
 erwise it is no better than the scorification 
 method and indeed in many respects the lat- 
 ter is to be preferred. 
 
 The scorification process is so much simpler 
 to use, easier to comprehend, and so satis- 
 factory in its working, that I shall give it the 
 greater prominence in this manual. 
 
 II. SCORIFICATION PROCESS. 
 
 The object of this process is to so act upon 
 an ore with heat, access of air, and certain 
 re-agents, that the precious metals shall be 
 driven out of their combinations with the 
 impurities of the ore (or if free, separated 
 
140 MANUAL OF ASSAYING. 
 
 from them), and be retained alloyed with 
 another metal, lead, and from which they can 
 afterwards be separated. 
 
 The chief re-agents are lead, in a. granu- 
 lated condition, and borax glass. 
 
 Besides these, silica, iron, and bi-carbonate 
 of soda are occasionally employed. 
 
 The ore, mixed with the lead, and covered 
 with the borax glass or other flux, is put into 
 a scorifier and subjected to heat in a muffle. 
 
 Under the action of the heat, the lead 
 melts, and being scattered throughout the 
 ore, seizes upon the gold and silver and set- 
 tles with them to the bottom of the scorifier. 
 The borax glass or other flux attacks the 
 gangue and impurities present, and uniting 
 with them and with litharge resulting from 
 oxidation of some of the lead, forms a slag or 
 glass, which floats upon the surface of the 
 molten lead. 
 
 So much for the theory of scorification; in 
 practice we follow in regular rotation the 
 steps here given: 
 
GOLD AND SILVER ORES. 
 
 141 
 
 a. Preparation of Charge (including weigh- 
 ing of ore, roasting, weighing of re-agents, 
 mixing, etc). 
 
 b. Scorification. 
 
 c. Cupellation. 
 
 d. Weighing the Gold and Silver Bead. 
 
 e. Parting. 
 
 f. Inquartation. 
 
 g. Weighing the Gold Residue. 
 h. Calculations. 
 
 a. Preparation of Charge. 
 
 Whatever subsequent treatment an ore is 
 to undergo, the quantity required for assay- 
 must be weighed first. Certain ores may 
 possibly be subjected to a preliminary opera- 
 tion known as roasting, but the ore must be 
 weighed out before this, not after. 
 
 If the ore in question is in a bottle, pour all 
 out upon a clean piece of black glazed paper or 
 piece of sheet rubber, or if it is in a box, it can 
 be sampled therein. Weigh the amount dcs 
 sired, sampling from various parts of the ore. 
 
142 MANUAL OF ASSAYING. 
 
 Roasting. — Whenever an ore contains a 
 large amount of antimony, arsenic, sulphur or 
 zinc, it can be first roasted, that is, heated till 
 the above mentioned substances are driven off. 
 This roasting is not often done, but when it is 
 advisable to do it, follow the directions here- 
 with given. 
 
 The roasting of ores for the scorification 
 process is performed as follows: 
 
 The carefully weighed ore is transferred to 
 a roasting-dish, and placed in the forward 
 part of the muffle before the latter has reach- 
 ed a dull red heat. The ore is to be continu- 
 ally stirred with a stout wire having a loop at 
 the end at right angles to the wire. Shortly, 
 minute sparks will be thrown off, and the ore 
 will begin to glow in places like burning char- 
 coal. Stirring must be kept up till the glow- 
 ing ceases, and the whole seems of one color. 
 It should yield to the stirrer like dry sand, have 
 no metallic lustre, and contain no hard lumps 
 or pieces adhering to the roasting-dish. 
 The dish and contents can now be moved to 
 
GOLD AND SILVER ORES. 1 43 
 
 the hottest part of the muffle and left unstirred 
 till fumes have ceased coming off, when the 
 ore is said to be "sweet." When finished, 
 take out, cool, and brush ore from dish. 
 
 If the ore is almost entirely pyrites of iron, 
 it needs no additional treatment during or af- 
 ter the roasting. If it be a mixture of iron 
 pyrites and copper pyrites, with the latter pre- 
 dominating, or copper pyrites alone, after tak- 
 ing out of the muffle and allowing to cool, 
 mix with a little carbonate of ammonia, cover 
 with another roasting-dish, and return to a 
 moderately warm part of the muffle till the 
 fumes have again ceased. Such Sulphates as 
 have been formed by the oxidation of sul- 
 phur in the ore are now converted into sul- 
 phate of ammonia, which being very volatile is 
 quickly driven off. 
 
 If the ore should contain much sulphide of 
 lead (galena), or sulphide of antimony, mix 
 some fine sand (or precipitated silica) with it 
 while roasting, as without it the minerals 
 mentioned would soon fuse, cake together and 
 
144 MANUAL OF ASSAYING. 
 
 adhere to the dish, thus spoiling the assay. 
 One fifth of an assay ton of ore will require 
 one gramme of silica, and so on. 
 
 If much antimonial and arsenical compounds 
 is present in the ore, it is advisable to mix 
 some charcoal, finely ground, with the ore, in 
 order to decompose the antimoniates and ar- 
 seniates formed. Let all the charcoal be 
 burned out before removing from the furnace. 
 
 I may add that in case the ore is a sulphide 
 (of whatever metal), with very little gangue, 
 it is best to add silica in roasting, in the pro- 
 portion given above. 
 
 If the laboratory is provided with gas, the 
 ore can be roasted in the usual roasting-dish 
 over the flame of a Bunsen burner, which will 
 work very nicely, as the temperature can be 
 regulated to any degree. 
 
 To continue with the preparation of the 
 charge : Number or letter the scorifier with 
 ruddle (liquid or lump), weigh the requisite 
 amount of granulated lead, divide approxi- 
 
GOLD AND SILVER ORES. 145 
 
 mately in halves, and transfer one half to the 
 scorifier. Upon it brush the ore (roasted or 
 not) and mix by means of a small steel spatula. 
 Pour the remaining half of the lead evenly 
 over the surface of the mixed ore and lead, 
 and over all sprinkle the borax glass. In simi- 
 lar manner prepare all the other charges. 
 
 A deviation from this method has been fol- 
 lowed by some assayers. '_ Their procedure is 
 to put, say \ of the lead at the bottom of the 
 scorifier, then the ore and \ of the lead mixed 
 previously, topping all with the remaining \ of 
 the lead. This change is due to the fear of 
 unacted-upon ore remaining at the bottom of 
 the scorifier. I am inclined to consider it an 
 almost unnecessary refinement. 
 
 In many assaying establishments, notably 
 the larger ones, the practice of marking scori- 
 fiers, cupels and crucibles does not obtain. 
 Instead of this, a systematic order of arrang- 
 ing these articles is kept up, either in or out of 
 the furnace, and this routine of position and 
 order of working is never varied, so that by 
 
146 MANUAL OF ASSAYING. 
 
 relative place a sample can always be identi- 
 fied. This plan is indeed a good one, and 
 perhaps imperative where very much work is 
 done, but for the beginner, for a time at least, 
 the custom of marking everything had better 
 be adopted. 
 
 b. Scorification. 
 
 Place the scorifiers, by means of the scori- 
 fier tongs (page 61, fig. 29) in the middle and 
 back of the muffle, which should be decidedly 
 hot, close the door and augment the draft. 
 
 Then begins the first operation, the melting 
 or fusion of the lead, due to intense heat and 
 absence of oxygen, which takes from three to 
 four minutes. 
 
 When the lead is liquid, open the door, thus 
 admitting a current of air to supply oxygen, 
 and which will also tend to diminish the heat 
 somewhat. 
 
 Now, in the case of ores containing or 
 retaining antimony, arsenic, sulphur or zinc, 
 a second operation, roasting, begins and con- 
 
GOLD AND SILVER ORES. 1 47 
 
 tinues till the greater proportion of the sub- 
 stances named have volatilized, the remainder 
 of them going into the slag. 
 
 During this time, the borax glass has melted 
 and begun uniting with the gangue of the ore 
 and with oxide of lead to form a slag which 
 surrounds as a ring the molten. lead. 
 
 As the scorification goes on, the melted 
 lead grows smaller and smaller by oxidation 
 and the volatilization of the greater part of 
 the oxide formed, while the ring of slag grad- 
 ually closes in and finally covers the lead, 
 which is seen no more. 
 
 Finally increase the heat for a minute or 
 two to fully liquefy the slag, which will finish 
 the process of scorification. 
 
 Remove the scorifiers, and pour their con- 
 tents into the cups of the scorification moulds 
 (page 65, figs, ■^'j and 38), which should not be 
 cold, covering each receptacle with its proper 
 scorifier to retain its identification. (If tieces- 
 sary these scorifiers can be again employed 
 for ores, etc.) 
 
148 MANUAL OF ASSAYING. 
 
 Instead of pouring, the leads can be allowed 
 to cool in their scorifiers, -but no advantage is 
 gained by this, and they take a longer time to 
 cool. 
 
 In either case, however, when cold, detach 
 the lead buttons from their slags, and hammer 
 each button into a clean cube with flat- 
 tened corners (fig. 70). Were the 
 Fig. 70. corners to be left sharp, they would 
 injure the cupel when the button came to be 
 dropped into it. 
 
 The weight of the button will vary accord- 
 ing to the conditions ; the nature of the ore, 
 the size of the charge, the heat of the furnace 
 and the length of time the charge was allowed 
 to remain in it, all exert an influence. A good 
 weight is from twelve to sixteen grammes, 
 which will make a cube of about one-half inch. 
 
 The button of lead is to be marked with 
 some identifying number or letter with the 
 point of a file or knife-blade. 
 
 The button should be perfectly malleable ; 
 if brittle it has retained antimony, arsenic, 
 
GOLD AND SILVER ORES. 1 49 
 
 zinc or litharge, which can be gotten ri.d of by 
 re-scorification. If the button is large no ex- 
 tra lead need be added, if small an assay ton 
 or two may be melted with it. 
 
 Again, the button may be very hard on ham- 
 mering or show red in places, and perhaps on 
 taking out of the scorification mould may 
 have mossy copper on the bottom. In such 
 cases the button must be re-scorified until no 
 more copper is seen, or until it is very malle- 
 able. Plenty of lead must be used to alloy 
 with the copper. 
 
 Since there is a greater loss of silver by 
 cupellation than in scorification, very large 
 buttons should be scorified down to a size 
 suited to the cupels. 
 
 Examine the slag, and if it contains any 
 globules of lead, hammer them flat, then place 
 them on top of the main button and cupel all 
 together. 
 
 The slag should be vitreous or glassy, and 
 of uniform character, its color depending upon 
 the nature of the ore. 
 
150 MANUAL OF ASSAYING. 
 
 The scorifier should be perfectly smooth in 
 its interior, that is, it should have no semi- 
 
 i 
 
 fused lumps adhering thereto. Occasionally 
 it may be corroded or eaten away, which does 
 not necessarily injure the assay, unless the 
 corrosion extends through the dish and allows 
 its contents to flow out upon the floor of the 
 mufifle. In such a case (when of course the 
 assay must be repeated) at once cover the 
 floor of the mufifle with dry sand or bone-ash, 
 using the muffle shovel (fig. 35), and scrape 
 out the mass adhering to it by means of the 
 hoe or scraper (fig. 39). If this cleaning 
 out of the mufifle after an accident by spilling 
 or leakage is not attended to, it leads to 
 either one or both of two evils : first, the 
 melted lead and borax attack the mufifle and 
 rapidly eat a hole through it ; secondly, they 
 stick to any scorifler or cupel placed in the 
 muffle, making it almost impossible to move 
 or remove either without breakage or loss of 
 contents. 
 
 The corrosion of the scorifier is a good hint 
 
GOLD AND SILVER ORES. 151 
 
 to add silica to similar ores, for usually it is 
 the lack of this in the ore that causes the, 
 abstraction of silica from the scorifier, though" 
 there are times when a mixture of much lead 
 and little ore is being scorified, that the Ifth- 
 arge formed by the oxidation of the lead itself 
 attacks the scorifier, and again, as in case of 
 compounds rich in copper (a copper matte for 
 instance), the oxide of copper attacks the 
 scorifier. 
 
 Sometimes in the process of scorification a 
 crust forms over the surface of the charge 
 and refuses to break. Such a crust is gener- 
 ally due to arsenical and antimonial ores pres- 
 ent, and may often be destroyed by dropping 
 in the scorifier some powdered charcoal 
 wrapped in a wad of thin paper. 
 
 The oxidation can also be commenced by 
 stirring the charge with a bent wire, until the 
 lead is uncovered and begins to act. Withdraw 
 the wire, break off the mixture adhering to the 
 end and return it (the slag, etc.) to the scori- 
 fier, as it will probably carry some of the ore. 
 
152 MANUAL OF ASSAYING. 
 
 c. Ciipellation. 
 
 This operation consists in oxidizing the 
 lead of the lead buttons, the litharge formed 
 by the heat being partly absorbed by the 
 cupel and partly driven up the chimney, leav- 
 ing the gold and silver together as a bead 
 upon the surface of the cupel. Other metals 
 that may have remained in small quantity 
 from the previous operations, are also oxi- 
 dized and so gotten rid of. 
 
 Take a good cupel (pages 73-76, fig. 49), in 
 weight about one-third greater than that of 
 the button that is to go in it, blow out any 
 dust or impurities from the interior, mark on 
 its sides in three or four places with ruddle or 
 the point of a file, its appropriate number or 
 letter, and with the aid of the cupel tongs or 
 cupel shovel and hoe, place it in the muffle and 
 there let it remain some four or five minutes 
 that it may acquire the temperature of the 
 furnace. 
 
 As can be inferred from the preceding 
 paragraph, the size of the cupel depends 
 
GOLD AND SILVER ORES. 
 
 153 
 
 upon the size of the lead button. And as 
 mentioned under cupel-making, it is a good 
 plan to have on hand cupels of various 
 weights. It is stated that a good cupel will 
 absorb its own weight of litharge, and further- 
 more, it is able to take a button heavier than 
 its own weight, for a large amount of litharge 
 (or oxide of lead) is driven off in fumes and 
 consequently does not enter into the body of 
 the cupel. But it is better to employ a cupel 
 the weight of which is from one-fourth to one- 
 third more than that of the button, for when 
 a cupel becomes nearly saturated with litharge, 
 the cupellation proceeds too slowly, when, on 
 the contrary, it ought to be somewhat 
 hastened, and cases occur that the cupellation 
 ceases, though there may be at the bottom of 
 the cupel enough unattacked bone-ash to 
 absorb the remaining lead. 
 
 When the cupel or cupels have been in the 
 mufifle a few minutes, and consequently have 
 become of the same temperature as the inte- 
 rior of the muffle, the lead button or buttons 
 
154 MANUAL OF ASSA YING. 
 
 are to be placed in them, each one in its 
 proper cupel, by means of the smaller curved 
 tongs (page 6i, fig, 27), and the mufifle-door of 
 the furnace closed, having previously, if neces- 
 sary, placed a couple of pieces of coke or 
 charcoal in the mouth of the muffle. 
 
 If the muffle has been of the proper tem- 
 perature, in a minute's time or less, all the 
 lead buttons will have quietly fused, and, on 
 opening the muffle door, each will be seen as 
 a little lake of molten metal, from which arise 
 fumes of oxide of lead. 
 
 The closing of the door at first is simply in 
 order to melt the lead buttons, by the in- 
 creased heat and absence of air. 
 
 It is very difflcult to give in words, direc- 
 tions for the proper conducting of this impor- 
 tant step of cupellation. Experience is the 
 best instructor. 
 
 In general, do not have the furnace too hot. 
 This is not a matter of so much importance 
 in the cupellation of the lead buttons from 
 gold ores, but in those from rich silver ores it 
 is such. 
 
GOLD AND SILVER ORES. I 55 
 
 " The heat is too great when the cupels are 
 whitish, when the fused metal is seen with 
 difficulty, and the scarcely visible fumes rise 
 rapidly " (Ricketts), and particularly when 
 the melted lead bubbles. 
 
 " The heat is too low when the fumes are 
 thick and fall, and when the unabsorbed lith- 
 arge forms lumps and scales" (Ricketts), 
 in short, to speak seemingly paradoxically, 
 when the muffle and contents look cold. 
 
 An extremely high heat is bad, but a low 
 heat is worse. " The following are indices of 
 favorable working : The muffle is reddish- 
 white, the cupel red, the fused metal luminous 
 and clear, the lead fumes rise slowly, and the 
 litharge is completely absorbed by the cupel." 
 So says Ricketts ; but concerning the last 
 count, opinions seem to differ. While some 
 assayers think all the lead should be in the 
 cupel, others declare the test of good working 
 to be in the presence of scales of litharge 
 around the inner circumference of the cupel. 
 In other words, the "feathering" shows that 
 
156 MANUAL OF ASSAYING. 
 
 the fire has not been too hot. Who shall 
 decide when doctors disagree ? 
 
 All this time, however, the buttons have 
 been growing smaller and smaller, by oxida- 
 tion and by volatilization and absorption of 
 the oxide, changing from flat liquids to con- 
 vex ones, and this reduction continues until 
 we reach the point when the last of the lead 
 leaves the bead. This is known as the 
 "brightening," "flashing," or "blicking." As 
 the button of gold, silver and lead arrives 
 near this stage it appears to revolve with 
 great velocity, and rainbow colors succeed 
 each other all over its surface. Finally a film 
 passes over the bead, and then no more 
 action is visible. 
 
 (With poor silver ores and ordinary gold 
 ores the final bead is so small that it is diffi- 
 cult, if not impossible, to see the "blicking," 
 but on beads from silver ores of any richness 
 the brightening shows well that the operation 
 of cupellation is concluded.) 
 
 Now move the cupel to the hottest place in 
 
GOLD AND SILVER ORES. 157 
 
 the mufifle, or increase the heat by closing the 
 muffle door, that the last traces of lead may 
 be driven off. One source of error in silver 
 assays is due to the assayer not getting rid of 
 all his lead from the beads, but instead he 
 weighs and reports it as silver. Better err by 
 under-reporting rather than over, so take the 
 chances of volatilizing a little silver from the 
 bead than to allow lead to remain with the 
 silver. A minute is generally sufficient to 
 drive off the last lead, but with ores contain- 
 ing more gold than silver, let the cupel remain 
 in the hot part three or four minutes, for 
 there is no danger of losing any gold in that 
 time. 
 
 Silver beads, on being suddenly brought 
 from the hot interior of the muffle to the 
 front where it is cooler, or out into the open 
 air, sometimes "spit," or "blossom ;" that is, 
 the bead sprouts or vegetates, forming foliated 
 protuberances all over its surface. This may 
 occasion loss, as the spitting throws off parti- 
 cles of the silver; hence guard against this as 
 
158 MANUAL OF ASSAYING. 
 
 much as possible by moving the cupel by 
 degrees to the front, and when at the mouth 
 of the muffle cover with an inverted hot 
 cupel. With beads weighing less than 30 
 milligrammes or thereabouts this need not be 
 done, but above that weight proceed carefully. 
 If the assayer is running a number of 
 assays, let him so arrange the cupels that 
 those intended for buttons from poor silver 
 ores or gold ores shall be in the centre or 
 hottest part of the muffle, while those for rich 
 silver ores shall be in the fore part or cooler 
 section. The reason for so doing- is this : sil- 
 ver is sensibly volatile at a high heat, and the 
 higher the temperature the greater the loss. 
 On the other hand the smaller the percent- 
 age of silver in a» silver-lead, the less loss of 
 this metal. By therefore placing the rich sil- 
 ver-lead in the cooler portions, the tendency 
 is to decrease the loss by volatilization. With 
 any furnace, the heat of which can not be in- 
 stantly controlled, the muffle often becomes 
 a little too hot for perfect cupellation. When 
 
GOLD AND SILVER ORES. 
 
 159 
 
 but few cupels are therein this does not matter 
 much, since they can be slid to the front ; but 
 it is of importance when the muffle is so well 
 filled that it becomes difficult or impossible 
 to move any particular cupel or group of 
 cupels to a cooler spot. By now putting in 
 the muffle a small cold scorifier or cupel, let- 
 ting it rest on the edges of four of the cupels, 
 the interior can be cooled down considerably. 
 Several scorifiers or cupels thus arranged have 
 quite a lowering effect on the temperature, at 
 least for a time. 
 
 When many cupels are being managed at 
 once make a chart of their relative positions 
 in the muffle, that there may be no "cases of 
 mistaken identity " afterwards, for with large 
 buttons in small cupels the litharge often 
 obliterates the ruddle marks. 
 
 If the furnace is too cold, cupellation ceases, 
 and the lead button is said to " freeze," form- 
 ing a bunchy mass which undergoes no fur- 
 ther action. A piece of charcoal laid upon 
 the cupel, and additional heat applied, will 
 
l6o MANUAL OF ASSAYING. 
 
 sometimes finish the cupellation, or the but- 
 ton may be dug out of the old cupel, wrapped 
 in a piece of lead-foil, and be re-cupelled in a 
 new cupel. The result either way is none too 
 accurate. 
 
 The final silver and gold bead from any 
 cupellation should adhere with some tenacity 
 to the cupel, have a bright rounded surface, 
 and appear frosted below. 
 d. Weighing the Gold and Silver Bead. 
 
 When cold detach the bead from its cupel, 
 using the point of a knife-blade and keeping 
 a finger on the bead while so doing if the 
 bead be small, for otherwise the exertion put 
 forth to loosen the bead might easily snap it 
 out of the cupel and past finding. 
 
 Lift the bead from the cupel by means of 
 delicate pincers (p. 84), and cleanse from 
 any adhering cupel dirt, by rolling in the 
 palm, by using a small stiff brush, or, if neces- 
 sary, by flattening a little by means of a small 
 steel hammer and anvil. If the bead be very 
 small fold it in three or four thicknesses of 
 
GOLD AND SILVER ORES. l6l 
 
 tissue paper to prevent its flying away under 
 the strokes of the hammer. 
 
 Weigh on the buUion scales in milli- 
 grammes and fractions. 
 e. Parting. 
 
 The' separation of gold and silver by dis- 
 solving out the latter is designated by the 
 term " parting." 
 
 The bead after weighing is flattened a little 
 if it has not been so treated before. Now 
 place in a little clean porcelain capsule or cru- 
 cible (fig. 53), and fill about a quarter full 
 with water (free from chlorine, see p. 106), 
 and add four to six drops of concentrated 
 nitric acid. No exact rule as to the amount 
 of acid to add can be given, nor indeed is it 
 necessary. But in general add drop by drop 
 till it begins to " bite " the bead, that is, when 
 the latter seems in violent motion and bub- 
 bles are thrown rapidly off. Instead of add- 
 ing concentrated acid to water containing the 
 bead, until it takes hold of the latter, the 
 assayer may use a diluted acid of known 
 
1 62 MANUAL OF ASSAYING. 
 
 strength. i6 parts of nitric acid of 41° Beaum^ 
 (specific gravity 1.4 1) with 30 parts of dis- 
 tilled water will make an acid of 21° Beaum^ 
 (specific gravity 1.16). This will do for ordi- 
 nary small beads ; for large ones, after having 
 treated them with the above 1.16 acid, add 
 some of 32° Beaume (specific gravity 1.26), 
 made by mixing 16 parts of the strong 41" 
 acid with 10 parts of distilled water. Make 
 these up in quantity and preserve in well 
 stoppered bottles. 
 
 Now place the capsule on a sand-bath or 
 wire triangle, and heat gently, not enough to 
 cause the acid solution to boil. After a time 
 no more action goes on. If there is no gold 
 in the bead, nothing will remain undissolved 
 in the capsule ; it will contain only the clear 
 solution of nitrate of silver, formed by the 
 silver dissolving in the acid. 
 
 In this case nothing further need be done 
 than to wash out the contents of the capsule 
 into a bottle containing silver residues. 
 
 But should one or more black specks be 
 
GOLD AND SILVER ORES. 163 
 
 seen at the bottom of the capsule or floating 
 about in the liquid, gold may or may not be 
 present ; at all events, these specks, however 
 small, must be treated as though they were 
 gold, Pour off the liquid above the black 
 particles, first lightly tapping the capsule in 
 order to cause the floating gold to settle to 
 the bottom. It is best to pour into another 
 clean porcelain dish, so that should the gold, 
 by some mischance, go over with the outpour- 
 ing solution, it may be recovered. Fill up the 
 capsule with water, agitate a little and warm 
 gently. This is to wash out the nitrate of 
 silver from the gold. Tap the gold to the 
 bottom, pour off the washings, and repeat the 
 washing. If there is much gold a third wash- 
 ing may be necessary. All this to insure 
 complete removal of the silver nitrate. 
 Finally drain off, wipe the capsule dry, 
 remove, by means of filter paper (or clean 
 blotting paper), any drops of water adhering 
 to the interior of the capsule (being careful 
 not to take away any of the gold), and heat 
 
1 64 MANUAL OF ASSAYING. 
 
 very gently at first till all moisture has been 
 driven off, then intensely for a minute or two. 
 The gold has now changed in color from black 
 to its normal yellow, and is very nearly pure, 
 enough so for all practical purposes. Let 
 the capsule and contents cool. 
 f. Inquartation. 
 
 When a bead of gold and silver contains 
 the gold in a greater proportion than about 
 one-third of the silver, it possesses the power 
 of resisting the solvent action of nitric acid. 
 A certain amount of the silver may dissolve, 
 according to the relative proportions of the 
 two metals, but the larger part of it will 
 remain so enveloped by the gold, that the 
 strongest acid will not attack it. 
 
 Hence we resort to inquartation or the 
 operation of producing an alloy of gold and 
 silver in such proportion that the latter metal 
 may be extracted by nitric acid. 
 
 By the color of the bead the assayer can 
 judge whether it needs to undergo this opera- 
 tion. If it be of a moderately yellow color or 
 
GOLD AND SILVER ORES. 165 
 
 a brighter yellow, it will probably need it. But 
 there can be no doubt of it, if it refuses to be 
 acted upon by the acid. 
 
 Remove it from the capsule and dry. 
 Weigh some thin and pure silver foil in 
 quantity about twice the weight of the bead. 
 Wrap the latter in the foil and place both in 
 a cupel (or in a small hole bored in the back 
 of the cupel) and fuse them well together in 
 the flame of a blow-pipe. When cool, remove 
 the now largely-increased bead from the 
 cupel, flatten and part as directed. 
 
 Instead of employing the blow-pipe, the 
 bead and silver can be enfolded in some 
 sheet-lead and be re-cupelled in the usual 
 manner. Indeed, if the original bead weighs 
 more than ten milligrammes, it will be easier 
 to alloy it by cupellation than by blow-piping, 
 and a much better fusion be obtained. 
 g. Weighing the Gold Residue. • 
 
 By means of a pointed slip of wood or 
 sharp knife-blade, transfer the gold (which 
 should be one scale or film) to the scale-pan 
 
1 66 MANUAL OF ASSAYING. 
 
 of the bullion balance, and weigh with exceed- 
 ing care, as usual in milligrammes and frac- 
 tions. It often happens that the minute black 
 pin-point of gold becomes too small to be 
 weighed after the heating. It can then be 
 reported only as a " trace" or "color." 
 h. Calculations. 
 
 By the use of the system of assay ton 
 weights, the calculation of the gold and silver 
 value of an ore becomes very simple. Two 
 examples will show this very clearly : 
 
 Example No. i. 
 
 Amount of ore taken -^ A. T. 
 
 Amount of test-lead used i^ " 
 
 Milligrammes. 
 
 Weight of gold and silver bead 8.50 
 
 " silver in \\ A. T. lead 25 
 
 True weight of gold and silver bead 8.25 
 
 Weight of gold in the bead i.io 
 
 Weight of silver in the bead 7.15 
 
 7-15 X 5 = 35-75 = 35|- milligrammes = 35I 
 ounces per ton of silver in the ore. 
 
GOLD AND SILVER ORES. 1 6/ 
 
 I. lo X 5=5-5 = si milligrammes = 5-|- ounces 
 per ton of gold in the ore. 
 
 VALUE OF THE ORE: 
 
 Gold — 5^ oun'ces @ $20.67 per oz $113.68 
 
 Silver— 3Sl " " 1.29 " 46.11 
 
 Total value per ton |iS9-79 
 
 Example No. 2. 
 
 Amount of ore taken -J A. T. 
 
 Amount of test-lead used i " 
 
 Mgrms. 
 
 Weight of gold and silver bead 231.90 
 
 Weight of silver in test-lead * 0.00 
 
 True weight of gold and silver bead 231.90 
 
 Weight of gold, " faint trace " 0.00 
 
 Weight of silver in the bead 231-9° 
 
 23 1.9 X 2=463.8=463 i8_niilligrammes=4633^ 
 ounces per ton of silver in the ore. 
 Value; 463.8x$i-29=$597.30 per ton. 
 
 Charges. — A charge which serves well for 
 the common run of ores, in which the metals 
 
 * Not deducted. Read remarks on testing of granulated lead 
 for silver, p. 119. 
 
l68 MANUAL OF- ASSAYING. 
 
 are not in excess of the gangue is the 
 
 following : 
 
 Ore iA.T. 
 
 Granulated lead i-J- . " 
 
 Borax glass 200 mgrms. 
 
 Use this for ores that do not contain much 
 copper or lead. The weight of the borax 
 glass is put down more to serve as a guide 
 than for any other purpose. It need not be 
 weighed accurately or even weighed at all ; 
 after a time the assayer will learn to use it in 
 pinches. 
 
 For ores with considerable copper, prepare 
 this charge : 
 
 Ore Vt A. T. 
 
 Granulated lead 2-J- " 
 
 Borax glass a trifle. 
 
 If arsenic, antimony, sulphur and zinc, 
 either one or all are present, the ore may or 
 may not be roasted. 
 
 In the latter case, and when not muc5 of 
 any one of the four elements named is present, 
 
GOLD AND SILVER ORES. 1 69 
 
 heat gently for a time, till the roasting in the 
 scorifier is done. 
 
 If rich in the said elements, a strong heat 
 can be applied at once, melting everything 
 down into a sort of matte, then proceeding as 
 usual. 
 
 In compounds very rich in copper, as cop- 
 per mattes, use no borax glass. 
 
 With sulphurets not roasted, litharge may 
 be sprinkled over the surface of the charge, 
 and works nicely. Weigh the litharge. 
 
 For tellurides, plenty of lead must be used, 
 either in the form of granulated lead or lith- 
 arge. The buttons may need repeated scori- 
 fications (20 parts of lead to i of ore). 
 
 With chlorides, use as low a heat as possi- 
 ble, all the way through until the charge has 
 covered over, then heat to complete fusion. 
 
 With antimonial and arsenical ores, char- 
 coal added during scorification often has a 
 good effect. 
 
 Ores having a great quantity of lime or 
 baryta will require more borax glass during 
 
170 MANUAL OF ASSAYING. 
 
 scorification (perhaps as much in weight as 
 the ore taken), and need a good heat. 
 
 Oxide of iron ores without silica should 
 have it added : i grm. per each \ A. T. ore. 
 
 For galena, \ A. T. with i A. T. lead works 
 well. A nail should be placed in the scorifier 
 to aid in desulphurizing. 
 
 Experience is necessary here. Work over 
 the particular ores you come in contact with, 
 until you learn them thoroughly. 
 
 III. CRUCIBLE PROCESS. 
 
 This process is the reverse of the scorifica- 
 tion method, for here (with one special 
 exception), the object is to secure fusion with- 
 out oxidation ; in fact, reduction or the 
 removal of oxygen is necessary. Litharge is 
 added to supply lead to extract the precious 
 metals, the oxygen of the litharge being 
 removed by the carbon of charcoal, argol, 
 cream of tartar,- etc. Bi-carbonate of soda 
 and carbonate of potash are mixed with the 
 ore to secure fluidity, and they with silica or 
 borax glass form a slag with the gangue of 
 
GOLD AND SILVER ORES. I 71 
 
 the ore. All these, or whatever of them are 
 used, are mixed and heated in a crucible till 
 perfect fusion is attained. 
 
 The various steps followed are the same as 
 those in the scorification assay, substituting 
 for "scorification," "crucible fusion." 
 
 Weigh the requisite amount of ore, samp- 
 ling as usual. If it is thought desirable, roast, 
 either in the muffle or over the flame of a 
 Bunsen burner. If the quantity taken be 
 over 2 A. T., roast in an ordinary frying-pan 
 over an open fire, having previously coated 
 the interior of the pan with ruddle or chalk. 
 
 A good charge for an ordinary silicious ore 
 (quartz, sand, etc.), free from sulphurets and 
 base metals, and commonly called a " dry 
 ore," is : 
 
 Bi-carbonate of soda 2 A. T. 
 
 Carbonate of potash \ " 
 
 Litharge li " 
 
 Ore I " 
 
 Borax glass \ " 
 
 Charcoal 4°° mgrms. 
 
 Salt cover. 
 
I 72 MANUAL OF ASSA YING. 
 
 Weigh out first the carbonates (approxi- 
 mately), and brush into a clean piece of black 
 glazed paper. Next weigh the litharge, then 
 the ore, followed by the charcoal, all three 
 very carefully, transfer to the top of the car- 
 bonates, add the borax glass and mix every- 
 thing thoroughly. 
 
 Brush the charge into a sand crucible, which 
 it should not more than two-thirds fill (an 
 " S " Battersea crucible is a good size). Tap 
 gently till contents are level, and cover with 
 from one-fourth to one-half inch of dry com- 
 mon salt. 
 
 The crucibles used are to be numbered or 
 lettered by means of liquid ruddle, in several 
 places, and in large characters, that there 
 may be no difificulty in identifying them after 
 fusion. This marking may be omitted if the 
 fusions are made in regular order. 
 
 Have the fire quite hot, place in it the cru- 
 cible, covered, bank around it with fuel, and 
 heat till contents are in quiet fusion, which 
 will be in from twenty-five to forty minutes, 
 
GOLD AND SILVER ORES. I 73 
 
 according to the temperature of the furnace, 
 nature of the fuel, character of the ore, etc. 
 
 When satisfied that the charge is well fused, 
 remove cover, lift out the glowing crucible by 
 means of the long handled crucible tongs (figs. 
 23 to 26), and tap it gently on a brick three 
 or four times (in order to gather together 
 into one button any little pellets of molten 
 lead that may be scattered throughout the 
 fused mass), then cover and let stand till cold. 
 
 Instead of having the fused charge cool in 
 the crucible, it can be poured into the scorifi- 
 cation mould which will hold the button and 
 some of the slag ; the excess of the latter can 
 run to waste. 
 
 Crucibles that have had their contents 
 poured out can be employed a second time 
 or even more often. In case of ores that 
 have shown little or no gold or silver, this 
 may do, but with ores of any richness, it is a 
 dangerous experiment to re-use their crucibles. 
 Accuracy should never be sacrificed to a spirit 
 of false economy. 
 
174 MANUAL OF ASSAYING. 
 
 Never try to cool a crucible by dipping it 
 into or holding it under cold water, as the but 
 partially cooled lead is liable to separate into 
 globules of various sizes, incurring danger of 
 loss. 
 
 When stone-cold, break the crucible or the 
 slag if the charge has been poured, saving a 
 piece of the slag for future examination and 
 comparison. Detach from all adhering slag 
 the lead button and hammer into shape as 
 usual. 
 
 If the button is too large, reduce by scorifi- 
 cation, cupel, weigh, part, etc., etc., as previ- 
 ously directed. 
 
 To consider the charge a little. The lith- 
 arge is to furnish the lead which is to collect 
 in one button the gold or silver or both, sus- 
 pected to be in the ore. By the action of heat 
 the carbon of the charcoal (or of argol, cream 
 of tartar, flour, etc., in other cases) takes away^ 
 the oxygen from the litharge or oxide of lead, 
 leaving it in the metallic state, when it sinks 
 down to the bottom of the crucible, showering 
 
GOLD AND SILVER ORES. I 75 
 
 through the ore, and carrying with it the pre- 
 cious metals. The borax glass unites with 
 the gangue of the ore, forming a slag. The 
 carbonates are simply fluxes, that is, aiding 
 the mixed mass to fuse, while the salt cover 
 protects the surface, and washes clean the 
 upper interior of the crucible. 
 
 When the crucible is broken, we find then 
 three things : at the bottom the lead button 
 containing the gold and silver, above it the 
 slag, and topping all a layer of fused salt. In 
 other cases, where iron has been employed to 
 take up the sulphur in pyrites of various 
 kinds, there may be found above the lead but- 
 ton, an iron or copper matte. 
 
 If it be desired to run a larger amount of 
 ore, say 4 A. T., make the soda in the charge 
 given 4 A. T., and the borax glass \ A. T., 
 letting the other ingredients remain the same. 
 
 When small amounts of galena or of iron 
 and copper sulphides are present, suspend one 
 or two iron nails in the charge, as in the lead 
 assay. 
 
176 MANUAL OF ASSAYING. 
 
 An ore mainly pyrites may or may not be 
 roasted. In the former case, diminish the 
 charcoal in charge given one-half, for there 
 will still be enough reducing compounds pres- 
 ent to bring down a good sized lead button. 
 Also replace the borax glass with i A. T, 
 of silica, though even then a little borax 
 sprinkled over the top of the charge will do 
 no harm. 
 
 Ricketts recommends the following charge: 
 
 Bi-carbonate of soda 4 A. T. 
 
 Litharge 2 " 
 
 Ore 2 " 
 
 Black flux substitute i " 
 
 Silica 2 " 
 
 Iron wire 12 loops 
 
 Salt cover. 
 If any matte is formed, scorify down with 
 the button. 
 
 Mr. A. H. Low, of Argo, Col., has given 
 me a good hint in the crucible running of sul- 
 phuret ores which I herewith jot down. Make 
 the fusion in the usual manner, and when it is 
 supposed to be completed, take out, pour ofif 
 
GOLD AND SILVER ORES. 177 
 
 as much of the slag as possible without losing 
 any of the lead. The button can now be 
 easily seen and if all the sulphur has not been 
 driven off, replace the crucible in the fire at 
 an angle, and scorify as it were till the sulphur 
 has gone, take out, pour, and the result will 
 be a clean button. 
 
 The same gentleman gives me a charge 
 where the sulphurets are not very abundant : 
 
 Bi-carbonate of soda 20 grammes. 
 
 Litharge 50 " 
 
 Ore i A. T. 
 
 Common borax, powdered 20 grammes. 
 
 Argol 4 " 
 
 Salt cover. 
 
 For ores richer in sulphurets, add from i to 
 10 grammes of nitre. 
 
 In general, for ores carrying copper in large 
 amounts, make the litharge in quantity three 
 times that of the ore. 
 
 If the gangue of an ore is lime or baryta, 
 
 instead of silica, make the borax glass at least 
 
 one-half as much as the ore taken, and in such 
 12 
 
178 MANUAL OF ASSAYING. 
 
 a case it is better to place the glass on the top 
 of the charge rather than to mix it with it. 
 
 If tellurides are to be treated by crucible 
 process, use an excess of litharge. 
 
 Mr. Geo. L. Stone has published the follow- 
 ing as a universal fiux for basic silver ores 
 (i.e., those in which the gangue is lime, 
 baryta, etc., for instance the three spars, calc- 
 spar, heavy-spar and fluor-spar) : 
 
 Bi-carbonate of soda 9 parts. 
 
 Borax glass 3 " 
 
 Argol I part. 
 
 " Mix thoroughly and keep on hand ready 
 for use. For one-third assay ton of ore, fill 
 the crucible about two-thirds full of the flux, 
 adding 2 or 3 iron nails if the ore contains 
 much sulphur." 
 
 From all the preceding, it will be seen how 
 absolutely impossible it is to make a charge 
 for all cases ; the ores must be studied to be 
 properly treated. 
 
GOLD AND SILVER ORES. I 79 
 
 SPECIAL CHARGE FOR GALENA. 
 
 Ore I A. T. 
 
 Bi-carbonate of soda 2 " 
 
 Carbonate of potash \ " 
 
 Nitre f " 
 
 Salt cover. 
 
 Treat in the usual manner. The action is 
 oxidizing, the nitre furnishing oxygen to a 
 portion of the galena, leaving enough lead 
 behind to retain any silver. 
 
 With all ores poor in silver, deduct the 
 silver known to be in the litharge, according 
 to the amount of the latter employed. 
 
CHAPTER II. 
 COPPER ORES. 
 
 Occurrence. — Copper is found both native 
 and in combination with many elements, 
 principally with sulphur as a sulphide or sul- 
 phuret, with oxygen as an oxide, and with 
 carbon, hydrogen and oxygen as a hydrated 
 carbonate. It has also been discovered asso- 
 ciated with most of the metals, common or 
 rare. 
 
 It is obtained for the arts and manufactures 
 mostly from the following ores . 
 
 1. Native copper (copper, sometimes accom- 
 
 panied by silver), when pure, lOO per 
 cent. 
 
 2. Cuprite (red oxide of copper), with 88.8 
 
 per cent copper. 
 
 3. Melaconite (black oxide of copper), with 
 
 79.8 per cent copper. 
 
 180 
 
COPPER ORES. l8l 
 
 4. Azurite (blue carbonate of copper), with 
 
 55.2 per cent copper. 
 
 5. Malachite (green carbonate of copper), 
 
 with 57.4 per cent copper. 
 
 6. Chalcocite (sulphide of copper), with 79.8 
 
 per cent copper. 
 
 7. Chalcopyrite (sulphide of copper and iron), 
 
 with 34.6 per cent copper. 
 
 8. Tetrahedrite (gray copper ore), copper 
 
 variable, normally contains about 38 per 
 cent* 
 
 Assay. — Of the many dry methods for the 
 testing of copper ores, it may safely be said 
 that no single one is very accurate. The vari- 
 ous metallurgical works usually have pro- 
 cesses or modifications of processes peculiar 
 to themselves, but which are always more 
 or less imperfect. Many of these processes 
 are complicated, and require great skill with 
 constant practice. 
 
 I have then thought it best to specify but 
 
 * See appendix for more extended list of copper minerals. 
 
1 82 MANUAL OF ASSAYING. 
 
 three assay methods, they being representa- 
 tive ones. 
 
 I. METHOD FOR NATIVE COPPER. 
 
 (As a simple mixture of rock and metallic 
 copper.) 
 
 Here the only action is fusion. 
 
 CHARGE. 
 
 Ore lo grammes. 
 
 Bi-carbonate of soda 20 " 
 
 Carbonate of potash 5 " 
 
 Borax glass i " 
 
 Salt and charcoal cover. 
 
 Sample ore as usual. Mix charge and pour 
 in " U " crucible. Put cover of \ inch salt 
 and then i inch of wood charcoal. Cover and 
 heat intensely for twenty to thirty minutes. 
 After cooling, break crucible and clean but- 
 ton from slag. Multiply weight by ten for 
 percentage of copper. 
 
 II. METHOD FOR OXIDES AND CARBONATES OF 
 COPPER, FREE FROM SULPHUR. 
 
 Here the action is reducing, followed by 
 
COPPER ORES. 183 
 
 the collection of the copper globules into one 
 button. 
 
 CHARGE. 
 
 Ore 10 grammes. 
 
 ■Black flux substitute 30 " 
 
 Borax glass 5 " 
 
 Argol 2 " 
 
 Salt and charcoal cover. 
 
 Use a " U " crucible, chalk-lined. Cover, 
 heat gradually for twenty minutes, then in- 
 crease to white-heat for forty minutes. Re- 
 move, tap and let cool. Results approximate, 
 the error augmenting by the presence of other 
 rrietals. 
 
 III. METHOD FOR SULPHIDES OF COPPER, WITH 
 ARSENIC, ANTIMONY, ETC. 
 
 The first step, roasting, is to drive off the 
 .sulphur and the volatile metals, arsenic, anti- 
 mony, zinc, etc., converting the copper into an 
 oxide. The second operation is reduction to 
 the metallic state, and the third the fusion 
 together of the copper with metallic lead 
 reduced from litharge. 
 
184 MANUAL OF ASSAYING. 
 
 CHARGE (rICKETTS). 
 
 Ore (roasted after weighing) .... 10 grammes. 
 
 Black flux substitute 25 " 
 
 Litharge 6 " 
 
 Borax glass S " 
 
 Argol 2 " 
 
 Salt and charcoal cover. 
 
 Chalk-lined "U" crucible. Heat for twenty 
 minutes. 
 
 The button of copper and lead must be 
 refined to be freed from the latter metal. 
 Place in a large cupel, already well heated, in 
 the muffle, and let it there remain till "bright- 
 ening " occurs, indicated by a peculiar green 
 color. As soon as this has happened, cover 
 cupel with coke or coal-dust, take out and 
 cool in water. 
 
 The greater part of the lead will have been 
 oxidized and have volatilized or have been 
 absorbed into the cupel. Results moderately 
 accurate, as a portion of the copper will have 
 oxidized, or the button may still carry lead. 
 
 (Read Mitchell, and Bodeman and Kerl, on 
 " Copper Assays.") 
 
CHAPTER III. 
 
 LEAD ORES. 
 
 Occurrence. — Lead is very rarely found 
 native (that is, as the pure metal), but occurs 
 combined with various elements, as antimony, 
 arsenic, carbon, chlorine, chromium, molyb- 
 denum, oxygen, phosphorus, selenium, sul- 
 phur, tellurium, tungsten, vanadium, etc. 
 Combinations of some of the above elements 
 with each other and with lead exist, either 
 alone or associated with such metals as cobalt, 
 copper, gold, iron, mercury, nickel, silver, 
 zinc, etc. 
 
 Many of these compounds are merely min- 
 eralogical curiosities, and will not be consid- 
 ered here. 
 
 The important workable ores are the fol- 
 lowing : 
 
 I. Galenite (galena, sulphide or sulphuret of 
 lead), when pure consisting of 86.61 per 
 
 cent lead and 13.39 P^"" '^^'^t sulphur. 
 
 185 
 
1 86 MANUAL OF ASSAYING. 
 
 2. Cerussite (white lead ore, carbonate of 
 
 lead), containing 77.52 per cent lead. 
 
 3. Minium (red oxide), with go.8o per cent 
 
 lead.* 
 
 Assay. — The method of assaying a lead 
 ore depends upon the nature of the ore. 
 
 I. METHODS FOR GALENA. 
 
 (Also for selenides, sulphates, and for galena 
 containing antimony and arsenic.) 
 
 A. By Crucible Fusion in Furnace. 
 I. With bi-carbonate of soda and metallic 
 iron. 
 
 CHARGE. 
 
 Ore 10 grammes. 
 
 Bi-carbonate of soda 25 " 
 
 Carbonate of potash 10 " 
 
 3 iron nails or 
 
 3 loops of iron wire. 
 
 Salt cover. 
 
 Prepare the sample according to the direc- 
 tions given on pp. 133-138. 
 
 * For more complete list of lead minerals see appendix. 
 
LEAD ORES. 1 87 
 
 Weigh first the carbonates, then the finely 
 pulverized ore, and mix thoroughly on glazed 
 paper. 
 
 (Read the notes on the " Crucible Assay of 
 Gold and Silver Ores," p. 1 70.) 
 
 Brush into a lettered or numbered^ small 
 sand crucible (size " U " of Battersea make), 
 and settle contents down. 
 
 If there is considerable pyrites in the ore, 
 sprinkle now over the surface of the charge 
 one gramme of finely powdered borax glass- 
 
 The three iron nails (eight-penny) are to 
 be held together by their heads with iron wire 
 (No.'i6), and then inserted, points down, in 
 the crucible, leaving a loop of the wire hang- 
 ing over the edge that the nails may be easily 
 and quickly withdrawn when the operation is 
 concluded. If wire only is used, bend a piece 
 of the No. 16, about six inches in length, in 
 the form of a horse-shoe with a loop above, 
 and in the loop hang two smaller pieces bent 
 in the form of hair-pins ; let all six points be 
 about on a level. Insert into the charge. 
 
1 88 MANUAL OF ASSAYING. 
 
 Finally pack on the surface of the charge 
 and around the nails or wire one-half inch of 
 dry salt. 
 
 Place the crucible in a moderately hot fire, 
 cover and surround with coke. 
 
 This process will require twelve to four- 
 teen minutes. 
 
 When fusion is complete, take off the cover, 
 remove crucible from fire, then by means of 
 small tongs stir the nails or wire loops around 
 in the molten mass once or twice, and while 
 in the hot fluid tap them against the side of 
 the crucible, then withdraw them, tap gently 
 the crucible and cover. All this should be 
 done as rapidly as possible. 
 
 When cold, break and hammer lead into 
 shape as usual. 
 
 The weight of the button, multiplied by ten, 
 will give the percentage of metallic lead in 
 the ore. 
 
 Tests of Good Work. — After fusion the 
 interior of the crucible should be smooth and 
 have no half-fused portions adhering to the 
 
LEAD ORES. 189 
 
 sides. The charge should be well settled to 
 the bottom arid have an even surface. The 
 slag should be uniform in character, and of a 
 purplish-black color. The lead should be at 
 the bottom in one button, and be perfectly 
 malleable. A glistening button indicates 
 undecomposed galena ; a brittle one the pres- 
 ence of antimony, arsenic or iron. 
 
 The alkaline carbonates act mainly as 
 fluxes, but a portion of the lead they convert 
 into a double sulphide of lead and soda (or 
 potash), which the iron desulphurizes, form- 
 ing sulphide of iron and metallic lead. 
 
 In order to learn the proper running of this 
 lead assay, it will be well for the student to 
 perform it at least ten times on the same ore. 
 
 2. With black flux substitute and metallic 
 iron. 
 
 CHARGE 
 
 Ore 10 grammes. 
 
 Black flux substitute 35 
 
 3 iron nails or 
 
 3 loops of iron wire. 
 
 Salt cover. 
 
I go MANUAL OF ASSAYING. 
 
 Treat in same manner- as for the first 
 method. Let remain in fire twelve or thirteen 
 minutes. 
 
 Add one gramme of borax glass to pyritic 
 ores. 
 
 The carbon of the flour of the black flux 
 substitute exerts an additional reducing 
 action. 
 
 Perform this assay a number of times for 
 practice. 
 
 The remarks given under the first method 
 are applicable here. 
 
 3. With cyanide of potash. 
 
 CHARGE. 
 
 Ore 10 grammes. 
 
 Cyanide of potash 30 " 
 
 Salt cover. 
 
 Time in furnace, about fourteen minutes. 
 Cover as usual. 
 
 In this process the sulphur of the ore unites 
 with the cyanide of potash, making the latter 
 a sulpho-cyanide. 
 
LEAD ORES. in I 
 
 Half-a-dozen runnings will be sufficient for 
 this rnethod. 
 
 These three methods can be performed 
 with satisfaction in Fletcher's gas furnace 
 (P- 45)- 
 
 B. By Crucible Fusion in Muffle. 
 4. With bi-carbonate of soda and argol (Rick- 
 etts). 
 
 CHARGE. 
 
 Ore 10 grammes 
 
 Bi-carbonate of soda 20 " 
 
 Argol 5 « 
 
 Flour 2 " 
 
 Borax glass i " 
 
 2 loops of iron wire. 
 Salt cover. 
 
 Mix the ore, soda, argol and tlour, and pour 
 into a small sand crucible large enough to 
 stand in the muffle used. Sprinkle over the 
 charge the fine borax glass, insert two pieces 
 of iron wire bent as hair-pins, and tamp down- 
 with from i to J inch dry salt. Use no cover. 
 
 Have the muffle at a bright red heat, and 
 place the crucible or crucibles therein ; after 
 
192 MANUAL OF ASSAYING. 
 
 about ten minutes of good heat, increase the 
 temperature for twenty-five minutes longer, 
 when the contents of the crucibles should be 
 in perfect fusion. 
 
 Take out, remove wires, tap, and let stand 
 covered till cool, do not pour, break, hammer 
 button, etc. 
 
 The size of the crucibles used will depend 
 upon the height of the interior of the muffle, 
 and the fact that the muffles usually employed 
 are small very often either necessitates a 
 smaller charge, or renders it impossible to use 
 this process. 
 
 For this work, one may either use the very 
 small crucibles of the ordinary form, surround- 
 ing each crucible with a little cup or platform 
 of fire-clay and sand mixed up with borax 
 water, that it may stand securely in the muffle, 
 or the special form for muffle fusions shown 
 in fig. 46. The latter is recommended, 
 
 C. By^Fusion in Scarifiers. 
 
 This is a modification of the lead assay 
 
LEAD ORES. 193 
 
 designed to be used where the muffles are not 
 large enough to admit of crucibles. 
 
 It is simply a substitution of scorifiers for 
 crucibles, using the same charges (reduced 
 one-half in quantity) as for crucible work, 
 and employing the muffle. 
 
 I have had good success with the third 
 charge, employing half the respective amounts, 
 thus : 
 
 5. With cyanide of potash. 
 
 CHARGE. 
 
 Ore S grammes. 
 
 Cyanide of potash 15 " 
 
 Salt cover. 
 
 For a " J " Battersea muffle, employ a 3^ 
 inch Battersea scorifier. Have the muffle red 
 hot, introduce scorifier, cover with 3^ inch 
 circular crucible cover (" G " of Battersea), 
 heat moderately for ten minutes, then in- 
 tensely for twenty. Remove cover, take out 
 scorifier, do not pour but let cool covered, 
 break, and shape lead button. * Multiply 
 
 weight by twenty for percentage. 
 
 13 ' 
 
1 94 MANUAL OF A SSA YING. 
 
 Comparison of Processes. — The cyanide of 
 potash process in crucibles gives the highest 
 results, the buttons are clean and malleable, 
 and the slags almost always uniform. I have 
 found it the one most quickly learned, and so, 
 on all accounts, I give it the preference. 
 
 The fourth process (crucible in mufifle) 
 comes next in percentage of lead obtained. 
 
 The second process (black flux substitute) 
 ranges next, and is quite satisfactory to work. 
 
 Very close in results to the preceding, is 
 the third process in scorifiers (No. 5, half 
 charge). 
 
 The first process (bi-carbonate of soda) 
 gives lower results than any of the others. 
 
 A method with ferrocyanide of potash, that 
 is sometimes used, I have omitted entirely, on 
 account of its inaccuracy. 
 
 II. METHODS FOR OXIDES AND CARBONATES. 
 
 (Cerussite, minium, etc.) 
 By crucible fusion in or out of mufifle. 
 
 6. With soda, potash and argol. 
 
LEAD ORES. 1 95 
 
 CHARGE. 
 
 Ore 10 grammes. 
 
 Bi-carbonate of soda 15 " 
 
 Carbonate of potash 5 " 
 
 Argol 5 
 
 Salt cover. 
 
 Mix as usual, and transfer to small crucible. 
 Cover, if fusion is made in the open fire, but 
 not if the muffle is used. Heat gradually for 
 about fifteen minutes, then somewhat more 
 strongly till fusion ensues. Take out, pour 
 or not, as desired. Cover if left in crucible 
 to cool. 
 
 Action reducing — -'the oxygen of the ore is 
 seized 'by the carbon of the argol, leaving 
 metallic lead. 
 
 7. With soda, a.rgol and borax. 
 
 Prepare a flux, in quantity, of the following 
 ingredients : 
 
 CHARGE. 
 
 2 parts bi-carbonate of soda. 
 2 parts argol. 
 
 I part common borax, in powder. 
 I part flour. 
 
1 96 MANUAL OF ASSAYING. 
 
 Have the above well mixed, then sifted, and 
 keep ready for use. 
 
 Fill about two-thirds full a so-called " 5 
 gramme" crucible (page 71), with the above 
 flux, add 5 grammes of the ore, and mix in 
 crucible. Put in muffle without cover. Keep 
 the heat as low as possible, without letting it 
 get too cold. 
 
 If the ore shows sulphurets, put in a nail or 
 two. 
 
 If the ore is quite calcic or barytic, make 
 the borax i^ parts and the flour f of a part. 
 
 For ores containing much manganese, add 
 to flux a little more borax and flour. 
 
 Concluding remarks. — At the best, the assay 
 of lead ores is inaccurate, mainly on account 
 of the volatility of the lead itself, though in 
 the case of galenite ores, it is supposed that 
 the galena begins to sublime before the de- 
 composition is effected. 
 
 Also, the lead button is liable to contain 
 antimony, iron, and zinc from the ore, or iron 
 
LEAD ORES.' 1 97 
 
 from the nails, wire, or iron salts employed in 
 the assay. 
 
 Try then to avoid an unnecessarily high 
 heat, remove assays as soon as fusion is ob- 
 tained, and use covers as much as possible. 
 
 See Mitchell, 5th ed., pp. 443-477 inclusive. 
 
APPENDIX. 
 
SECTION I. 
 
 SPECIAL METHODS. 
 
 I. ASSAYING OF THE VARIOUS MINERALS CON- 
 TAINED IN AN ORE. 
 
 It is sometimes desirable to know where the 
 gold and silver are located in an ore, that is, 
 which minerals carry them to the greater 
 extent. This can not always be done, for the 
 various minerals may be so thoroughly com- 
 mingled that separation will be impossible. 
 But in other cases, it can be done with suc- 
 cess. For example, an ore is found to be 
 made up of three distinct minerals, blende, 
 galena and pyrites in a quartz gangue. Weigh 
 the piece selected, and crush roughly in a 
 mortar, taking care not to lose any, and pour 
 out on a clean surface, as a sheet of white 
 paper. With a pair of pincers pick out such 
 pieces of the quartz as show none of the min- 
 
202 MANUAL OF ASSAYmC. 
 
 erals mentioned, and reject them. Then it 
 will be comparatively easy to put aside, in 
 three piles, the minerals, each quite free from 
 the other two. By carefully crushing the 
 remaining mixed pieces, the entire lump will 
 finally be separated into its three component 
 valuable minerals and the worthless gangue. 
 
 Weigh each lot, and assay the whole of 
 each or fractions thereof. 
 
 To show method of calculation, I give the 
 following 
 
 Example. 
 
 Weight of sample of ore, 500 grammes, 
 Which was composed of: 
 
 Pyrites, 40 grammes. 
 
 Blende, 60 " 
 
 Galena, 100 " 
 
 Quartz gangue, 300 " 
 
 500 grammes. 
 
 Percentage of py rites =-5y\j-x 100= 8 
 
 " blende =^\X 100= 12 
 
 " " galena =^fX 100= 20 
 
 " quartz =11^X100= 60 
 
APPENDIX. 203 
 
 Pyrites. — The 40 grms gave 10 mgrms gold — no silver: 
 -gVVX 29.166=0.58332=^5% of an ounce per ton. 
 
 Blende. — 10 grms gave 4 mgrms silver — no gold: 4X6 
 = 24; -5^X29.166=1.39 oz. silver per ton. 
 
 Galena. — 20 grms gave 160 mgrms silver — trace of gold: 
 ' 160X5=800; 1^^X29.166=46.6 oz. silver per ton. 
 
 II. ASSAYING OF ORES CONTAINING FREE GOLD 
 OR FREE SILVER. 
 
 The average ore does not carry the precious 
 metals in the free state. But when they are 
 present in such form, proceed as follows: 
 
 Crush the sample selected, having first 
 weighed it. Pulverize as usual, and sift, 
 using the box sieve. As a result we shall 
 have two things, the finely powdered siftings 
 below and more or less free metal in scales 
 on the sieve. 
 
 Weigh the scales, and, as a check, the sift- 
 ings. The weight of the latter should be but 
 a trifle less than the difference between the 
 original weight and that of the scales, if care 
 has been taken in pulverizing. 
 
 If not too large an amount, all the scales 
 
204 
 
 MANUAL OF ASSA YING. 
 
 should be wrapped in pure lead-foil, and 
 cupelled directly. If quite an amount be 
 present, simply scorify down in the usual 
 manner. 
 
 Take a weighed fraction (one-half, one- 
 ♦tenth, one-twentieth, as the case may be ) of 
 the siftings, and assay by scorification or cru- 
 cible process. The number of milligrammes 
 gold and silver obtained are each to be multi- 
 plied by the proper fraction to ascertain the 
 amounts present in the entire bulk of the 
 siftings. Add the gold thus calculated to be 
 in the whole of the siftings to the amount 
 found to be in the scales, and the same with 
 the silver. If the metal is all free gold or all 
 free silver, the calculations are still simpler. 
 
 To make this matter perfectly clear to 
 those who may still be puzzled, I illustrate 
 by an example as given by Prof. Ricketts in 
 his "Notes on Assaying": 
 
 " The sample presented for assay weighs 
 485 grms. Pulverized and sifted in a box 
 sieve it gave : 
 
APPENDIX. 205 
 
 A. sSifted ore 480 grms. 
 
 B. Metallic scales 5 " 
 
 A. Sifted Ore. — lo grms. gave by cruci- 
 ble assay : • 
 
 Gold 4 mgrms. 
 
 Silver, after deduction of the sil- 
 ver in the litharge 14.3 
 
 Hence, the total precious metal in the sift- 
 ings is : 
 
 Gold *3^X48o= 192.0 mgrms. 
 
 Silver 1^^X480=686.4 
 
 B. Metallic Scales. — These melted with 
 lead gave a button of, say 60 grms., which was 
 rolled out and 10 grms. taken for cupellation, 
 which yielded : 
 
 Gold 2.6 mgrms. 
 
 Silver 500.0 " 
 
 Hence, the total precious metals in residue 
 must be : 
 
2o6 MANUAL OF ASSAYING. 
 
 Gold II X 60= 15.60 mgrms. 
 
 Silver VV X6o=30oo.oo " 
 
 Total : 
 Gold in siftings 192.00 " 
 
 " " residue 15.60 " 
 
 Gold in ore taken 207.60 " 
 
 Hence : 
 -'^^"x 29. 166 (value of an assay ton)=gold 
 per assay ton of original ore. 
 
 Silver in total siftings 686.40 mgrms. 
 
 " " residue 3000.00 " 
 
 " " ore taken 3686.40 " 
 
 Hence : 
 
 ^^^l^" X 29. 166 (value of an assay ton) = 
 silver per assay ton of original ore." 
 
 On this same matter of the calculations of 
 the value of an ore containing free gold or 
 silver, I append an article contributed by Mr. 
 F. A. Lowe to the " Engineering and Mining 
 Journal" (Vol. xxxiii, No. 6, Feb. 11, 1882, 
 p. 81): 
 
APPENDIX. 207 
 
 " METALLIC SCALES. 
 
 In using the metric system in assaying ores 
 carrying native silver or metallic scales, the 
 following method will be found to be simple 
 and expeditious. It is based upon the value, 
 per ton, in ounces, of i milligram of metallic 
 scales in i gram of ore=29. 166 per ton. 
 
 To find approximately the metallic scales, 
 per ton, from any amount of ore taken as a 
 sample, divide the whole weight of the sample 
 taken into 29.166, and multiply the quotient 
 by the weight (in milligrams) of the metallic 
 scales cupelled. 
 
 Example. 
 
 Weight of sample taken, 400 grams. 
 29. 166 -=-400=0.07291 
 
 Assay value of siftings per ton 300.00 ounces. 
 
 Weight' of metallic scales cupelled = 500 
 
 milligrams; hence 500 X 0.07291 = 34.45 " 
 
 Total value per ton of such samples. . . .334.45 " 
 
 As 100 grams from any well-sampled sam- 
 ple is the most convenient amount on which 
 to base the approximate value per ton, by 
 
2o8 MANUAL OF ASSAYING. 
 
 simply dividing the weight, in milligrams, 
 of the metallic scales cupelled, by 3.427, and 
 adding the quotient to the assay value of the 
 siftings, the same result will be obtained as 
 when 100 grams is multiplied by 0.29166, and 
 the result added to the siftings. 
 
 Example. — First Method. 
 
 Weight of sample, 100 grains. 
 
 29.166-7-100=0.29166 
 Assay value of siftings per ton 200.6 ounces. 
 
 Weight of metallic scales cupelled =500 
 
 milligrams; hence 500X0.29166= .... 145.8 " 
 
 Total value per ton of such samples 345.8 " 
 
 Second Method. 
 
 Weight of sample, 100 grams. 
 
 Assay value of siftings per ton 200.0 ounces 
 
 Weight of metallic scales cupelled = 5 00 
 milligrams; hence 5oo-=-3.427= i4S-8 
 
 Total value per ton of such samples. . .345.8 " 
 
 3.427 is the weight, in milligrams, of me- 
 tallic scales, corresponding to i ounce per ton, 
 obtained from 100 grams as a sample. To 
 
APPENDIX. 209 
 
 determine approximately the whole amount 
 of silver, in milligrams, in a sample, divide 
 the assay amount, usually -^ assay ton for 
 silver ores, into the whole weight of sample 
 minus weight of metallic scales cupelled, and 
 multiply the quotient by the weight of button 
 obtained from the sif tings; then add weight 
 of metallic scales cupelled. 
 Example. 
 
 Milligrams. 
 
 Weight of sample, i kilogram = 1,000,000 
 
 Weight of metallic scales cupelled 1,000 
 
 1,000,000—1000-7-2916 = 342-5 
 
 Weight of button obtained from o.i assay 
 
 ton 5° 
 
 Then 342.5 X 50= total amount of silver in 
 
 the siftings = 17,125 
 
 Total amount of silver in the sample, 17,125 
 
 -f 1000 = 18,125 
 
 or .58 ounce troy. 
 
 Remembering that 31.17 grams equal i 
 ounce troy, and 28.40 grams equal i ounce 
 avoirdupois, any weight avoirdupois can be 
 easily reduced to the metrical system and the 
 whole amount of silver to troy ounces." 
 14 
 
2IO MANUAL OF ASSAYING. 
 
 III. ANALYSIS OF COPPER ORES. 
 
 The wei process or analysis of copper ores 
 is so much more accurate than the dry pro- 
 cess or assay, that it should always be 
 employed when practicable. 
 
 As in the assay of copper, so in the anal- 
 ysis, there are many methods, here included 
 under three heads ; volumetry, gravimetry 
 and electrolysis. While there are good ways 
 of determination among the first two classes, 
 yet I prefer one in the third, owing to its 
 simplicity, accuracy, freedom from intricate 
 calculation, and the ease with which it can be 
 acquired. 
 
 The process I now describe is known as the 
 Luckow method, and consists, briefly defined, 
 in dissolving the copper out of its combina- 
 tions by means of acids, and then depositing 
 it as the metal itself upon another metal, 
 platinum, by the action of an electric current. 
 
 It makes no difference whatever in this 
 method, how the copper is originally com- 
 bined, whether as a sulphide or in a mixture 
 
APPENDIX. 2 I I 
 
 of sulphides of other metals, an oxide or car- 
 bonate, a matte or an alloy ; the copper 
 comes out as metallic copper in any case. * 
 
 PROCESS. 
 
 Prepare the sample in the usual manner, 
 being sure to use a loo-mesh sieve. Sample 
 and weigh out very carefully on the ore scales, 
 one gramme, if the ore be at all rich (say 
 above 20 per cent), or five grammes if it be 
 poor in copper (below 20 per cent). 
 
 Brush into a casserole, i.e., a porcelain 
 evaporating dish with a handle (fig. 58), and 
 cover with a clock-glass (fig. 52), of slightly 
 larger dimensions, and add 10 cubic centi- 
 metres of pure and concentrated nitric acid, 
 by means of a 10 c.c. pipette (fig. 59). 
 
 Now place the casserole either on a sand- 
 bath (a common tin plate holding some dry 
 
 * If accessiblS, consult a very interesting paper, entitled ' ' Com- 
 parison of Various Methods of Copper Analysis," by Mr. W. E. C. 
 Eustis of Boston, which was read at the August, 1882, meeting in 
 Colorado of the American Institute of Mining Engineers, and is 
 to be found among the published transactions of that society. 
 
212 MANUAL OF ASSAYING. 
 
 sand), or on a piece of wire gauze, supporting 
 either on a ring-stand (fig. 63), and heat with 
 a Bunsen burner (fig. 64), or alcohol lamp. 
 Continue this heating some little time, then 
 let cool. When cold, add, from another 
 pipette, 5 c.c. of pure and concentrated sul- 
 phuric acid, and heat to boiling till no more 
 red fumes are given off, but in their stead 
 dense white vapors are delivered. 
 
 The red fumes are from the nitric acid, the 
 excess of which we wish to get rid of, which 
 is done by means of the sulphuric acid, and 
 the white fumes show that the former acid is 
 about gone. Let the casserole stand till cold. 
 
 Now add about 50 c.c. of distilled water, 
 stir with a glass stirring rod, heat, and let 
 stand till any undissolved matters have set- 
 tled to the bottom of the casserole. 
 
 While this is doing, prepare for filtering, 
 that is the separating of the dissolved copper 
 (and other metals) from the undissolved 
 silica, etc. Place in proper position a filter- 
 stand (fig. 68), glass funnel (fig. 57), and 
 
A PPENDIX. 2 I 3 
 
 glass beaker (fig. 56). The filter-paper is 
 fitted by cutting a piece in a square, then 
 folding in half, diagonally, and then into quar- 
 ters ; it will form a triangular figure, and if the 
 corners are 'cut off in a curved line, a circle 
 will be formed on spreading out. Upon open- 
 ing the folded paper so that three thicknesses 
 come on one side and one on the other, a 
 filter is obtained, which is placed in the funnel 
 and wetted by means of the wash-bottle (fig. 
 51). This useful piece of apparatus is oper- 
 ated by simply blowing in at « ; a fine stream 
 of water at once issues from b, which can be 
 directed against any part of the funnel. 
 
 Filter the liquid in the casserole by holding 
 the glass-rod outside the lip of the vessel, 
 allowing the solution to run down the rod 
 into the funnel, till the latter is nearly full. 
 Repeat the operation until nearly all the solu- 
 tion has passed through the funnel, and the 
 sediment (if there is any) begins to flow over. 
 Examine the residue, and if it is dark-colored, 
 it is best to repeat the treatment with acids. 
 
214 MANUAL OF ASSAYING. 
 
 Generally, however, once Is enough. Finally 
 wash the contents of the casserole into the 
 funnel, which fill three or four times with 
 water, which will be sufficient to wash out all 
 the copper solution. 
 
 The residue on the filter-paper consists of 
 silica and other substances insoluble in the 
 acids used. It should contain no copper. 
 
 The filtrate, that is the filtered liquid, con- 
 tains the copper as sulphate (with perhaps 
 some nitrate), also it may be, iron, lead, etc., 
 but these do no harm. 
 
 The next thing is to deposit the copper 
 upon platinum. We may use a vessel entirely 
 of platinum, or a copper dish lined with plati- 
 num, or a horseshoe shaped strip of platinum 
 suspended in a glass beaker. In case the 
 operator possesses the platinum or platinum- 
 lined dish, clean it thoroughly by washing. If 
 it is a new vessel, best rinse it first with some 
 solution of caustic soda or potash to remove 
 grease, then rub it gently with a little Jine 
 sand, thus giving the interior a surface favor- 
 
APPENDIX. 
 
 215 
 
 able for deposition. Be sure to wash off all 
 the soda or potash solution and sand, then 
 warm till it is perfectly dry. When cool, 
 weigh carefully on the ore scales and note 
 the weight. Pour the copper solution into 
 the platinum dish, using the glass-rod, which 
 rinse off with water into the dish; finally rinse 
 out the beaker with a little water into the 
 dish. 
 
 We now have a weighed dish containing 
 copper in solution from a known weight of 
 ore. It remains to connect it with a battery, 
 which latter is now described. 
 
 Fig. 71. 
 
 Fig. 71 represents two cells of what is com- 
 monly known as the " Bunsen Carbon," which 
 
2l6 MANUAL OF ASSAYING. 
 
 form a battery powerful enough for our pur- 
 pose. A quart size will be about right. It 
 consists of a glass cell or jar to contain the 
 dilute sulphuric acid, a cylinder of cast-zinc, 
 of which the ends do not quite meet ; a po- 
 rous earthenware cup, to hold nitric acid, and 
 a rod of compressed carbon. 
 
 .Prepare a mixture of strong sulphuric acid 
 (ordinary commercial) and water in the pro- 
 portion of one part of the former to ten of the 
 latter, observing the precaution of pouring the 
 acid into the water, never the reverse. Let 
 the zincs stand in this acid solution for two or 
 three minutes, then pour over them a little 
 mercury, and rub with a piece of soft rag tied 
 around a stick, till the entire surface, inner 
 and outer, of the zincs, is coated with amal- 
 gam. 
 
 Put each cell properly together and fill the 
 glass jars with the sulphuric acid mixture, just 
 covering the tops of the zincs. Next, nearly 
 fill the porous cells with concentrated (com- 
 
APPENDIX. 217 
 
 mercial) nitric acid. * See that the binding 
 screws are filed bright, also the connecting 
 wires, to make good contact. Arrange appa- 
 ratus as follows : 
 
 The zinc of the first cell is to be united 
 with the platinum dish by means of a coil of 
 copper wire underneath the latter. A strip of 
 platinum foil (cleaned with potash solution 
 and sand) just dips into the solution of cop- 
 per, and is connected to the carbon of the 
 second cell by a copper wire. Another wire 
 between the zinc of this latter cell and the 
 carbon of the first, completes the circuit. 
 Cover the dish with two pieces of window- 
 glass, to prevent loss by spattering. 
 
 The copper at once begins to line the inte- 
 rior of the dish, and in from four to six hours 
 the deposition will generally be complete. 
 Time is often gained by starting the action at 
 evening, and letting it run all night. 
 
 Prove the complete deposition of the cop- 
 
 * A bench of from two to six so-called "gravity" cells will do 
 instead of the pair of Bunsen Carbons, and are more constant. 
 
2l8 MANUAL OF ASSAYING. 
 
 per by taking one drop of the solution and 
 adding to it one drop of sulphuretted hydro- 
 gen water, mixing the two on a white surface 
 (cover of a porcelain capsule). If no colora- 
 tion ensues, the copper has all been thrown 
 down ; if a black discoloration follows, then 
 there is still copper in solution. In this latter 
 case, continue the current till the test is 
 negative. 
 
 In the former case, pour the contents of the 
 dish into a clean beaker, rinse the dish, the 
 under surfaces of the glass plates and the 
 platinum strip, into the same beaker. On 
 adding to the contents of this beaker an 
 excess of aqua ammonia, no blue coloration 
 should be seen. 
 
 Add a few drops of alcohol to the dish, 
 rinse around and drain off. Set fire to the 
 little remaining in the dish, and when the lat- 
 ter is cool, weigh. The difference between 
 this latter weight and the original weight of 
 the dish is metallic copper. I give an 
 example : 
 
APPENDIX. 2 1 9 
 
 Weight of ore taken =i gramme. 
 
 Grammes. 
 
 Weight of platinum dish and copper=:56.4o8 
 
 empty=ss.6s9 
 
 " " copper from i gramme= 0.749 
 0.749 multiplied by 100, gives 74.9 per cent 
 of metallic copper in the ore. 
 
 As before mentioned, instead of the platinum 
 dish, which is quite expensive, a glass beaker 
 can be used to contain the copper solution. 
 A second platinum strip, on which is to be 
 deposited the copper, must be used here. 
 Dip this in the beaker and connect with a 
 zinc element. The platinum strip in straight ■ 
 form connects with the other carbon as usual. 
 
 If the copper should form dark colored on 
 the platinum, it is because the solution is too 
 acid. Nearly neutralize with a little ammo- 
 nia water, to counteract its bad effect. Too 
 strong a current should also be avoided.^ I 
 have given this process well in detail, but it 
 will be found to be much easier learned than 
 described. It is a very pretty and satisfactory 
 method. 
 
2 20 MANUAL OF ASSAYING. 
 
 Volumetric analysis of copper ores. 
 
 If very many tests of copper ores, slags, 
 mattes, etc., are to be made daily, the volu- 
 metric process would best be used, for while 
 it is not so accurate as the battery process 
 above described, it is much more rapid. 
 
 Make a solution of the copper, as though it 
 were to be determined by battery process, 
 using one gramme of ore. 
 
 It is the safest plan to remove the copper 
 from all other metals present, by adding to 
 the diluted sulphuric acid solution, say three 
 grammes of pure metallic zinc. In about 
 fifteen minutes all the copper is precipitated. 
 (Make sure of this by pouring solution into a 
 platinum dish and adding sulphuric acid and 
 zinc. If no copper shows on platinum after a 
 minute or so, the precipitation is complete.) 
 Now add a large excess of sulphuric acid to 
 solution in beaker to dissolve the excess of 
 zinc. Pour off liquid, wash copper with 
 water, and re-dissolve in nitric acid. 
 
 Add ammonia water till solution is deep 
 
APPENDIX. 221 
 
 blue and titrate with cyanide of potassium 
 solution. 
 
 Consult authorities on volumetric analysis. 
 
 IV. AMALGAMATION ASSAY OR LABORATORY 
 
 MILL RUN. 
 
 By M. G. Nixon, M.E. 
 
 The wet copper assay bears somewhat the 
 relation to the fire copper assay that the fire 
 gold assay does to the amalgamation gold 
 assay. 
 
 In a certain sense, no one cares to know the 
 ultimate amount of metal that an ore contains. 
 What is desired in practice, is the yield under 
 the most skilful treatment, and this informa- 
 tion is approximately obtained by fire for 
 copper, and the amalgamation process for 
 gold. 
 
 There are those so practised in "panning," 
 that from a "panful" of "pulp" they can 
 very closely guess the yield by the number of 
 " colors " and their size. Of course this 
 method is not very popular, nor can it ever be. 
 
222 MANUAL OF ASSAYING. 
 
 Something more a matter of weighing, and 
 less a matter of judgment and practice is 
 required. 
 
 The amalgamation assay in its simplest 
 form consists in "panning" a weighed amount 
 of " pulp " with few or many drops of mercury, 
 accordingly as the ore is poor or rich. The 
 tailings are washed out as clean as may be, 
 the pan is then placed over a fire to dry and 
 then what remain^ of dirt and dust is blown 
 out with the breath ; the pan is again placed 
 over the fire and the mercury volatilized, leav- 
 ing the gold ("retort") ready for weighing. 
 This process is quite largely followed by pros- 
 pectors in some of our free-gold districts. 
 
 An improvement on the method just de- 
 scribed consists in grinding the pulverized ore 
 in a large iron mortar with which water and 
 mercury are introduced, with the pestle. 
 When the grinding is complete, the whole is 
 washed into a pan to be collected and finished 
 as before. 
 
 These methods are not recomrriended, but 
 
APFENDIX. 223 
 
 may be resorted to when other apparatus can 
 not be obtained. 
 
 The third method consists in grinding say- 
 ten or twenty pounds of ore in a laboratory 
 " arrastre " by hand two hours or more, or, 
 where possible, by power half as long. It is 
 well to pass the ore through a 40-mesh sieve 
 before placing it in the "arrastre." From 
 two to four ounces of mercury are then 
 squeezed through a piece of chamois skin, or 
 blown through a tube the end of which is 
 drawn out so as to make a pin-hole exit. 
 Having put the pulp and mercury into the 
 "arrastre" mortar, a piece of potassium cya- 
 nide as large as the end of one's little finger 
 is dropped in, the grinder adjusted, enough 
 water added to cover the ore, and the grind- 
 ing performed. After it is finished, the 
 grinder is first washed off into a collecting 
 pan, then the mortar with its contents is 
 treated in the same manner. The best way 
 to collect the amalgam is to hold the pan 
 under a running stream or water faucet, and 
 
2 24 MANUAL OF ASSAYING. 
 
 very gently to stir it with the hand. The 
 amalgam is then placed in chamois skin and 
 squeezed so as to get rid of as much mercury 
 as possible. 
 
 The residue is next placed in a small, iron 
 retort, and what remains of the mercury is 
 driven off by heat gradually increased. Of 
 course, for reasons of economy, it is well to 
 condense the mercury; it may then be sold to 
 mills or others, but neither that portion con- 
 densed nor that squeezed through the chamois 
 should be used over again, since it is almost 
 impossible to get rid of the last traces of 
 gold. The " retort " is then to be scorified, 
 cupelled, inquarted, etc., etc.* 
 
 The writer has saved 93 per cent of the fire 
 
 *An amalgam obtained as a result from either the preceding 
 method, from- panning with mercury, or from any other process, 
 can be treated in the following manner, provided it is not in too 
 great quantity. 
 
 Into a new scorifier (say 2^ inches in diameter) introduce the 
 amalgam after it has been separated from the free mercury by 
 squeezing in a piece of chamois skin. On top of the scorifier 
 place another of same size, inverted, having first bored through it 
 a hole about yi inch in diameter. By rubbing down a little the 
 tops of the scorifiers, and painting their edges with a thick wash 
 
APPENDIX. 225 
 
 assay on the same ore that a mill at the 
 time under his superintendence returned 89 
 per cent. 
 
 V. PAN TEST FOR GOLD. 
 ("panning.") 
 
 The estimation of gold in ores in which the 
 metal is in the free state is unreliable by 
 
 of ground chalk and water, all danger of loss of amalgam by its 
 spirting through at the sides, is avoided. 
 
 Heat in muffle or furnace till the mercury has been driven off 
 in vapor through the fine opening above, take out, let cool and 
 remove the upper scorifier. 
 
 Now put the chamois skin on top of the residue in the scorifier 
 and burn to ashes in muffle or furnace, remove a second time and 
 cool. 
 
 Finally mix the residue and ashes with granulated lead and 
 scorify, Re-scbrify with more lead if the resulting button is brit- 
 tle. Cupel in the usual manner and treat the bead obtained as 
 gold bullion. 
 
 If it is not thought worth while to save the mercury, the fluid 
 amalgam can be treated directly as described without first squeez- 
 ing through a chamois skin, in which case the accompanying step 
 of burning the latter, etc., is dispensed with. Heat very gradually. 
 Even with this apparatus the mercury can be saved by attaching 
 to the upper scorifier a small iron tube which bends over and dips 
 into water. • 
 
 The. advantages of the above method are that it is simple, easy 
 to operate, and that all the work (up to the cupellation) is done in 
 one vessel, and so any liability to loss of gold in transferring from 
 a retort, etc., is done away with. Furthermore, working with 
 small quantities of amalgam, in even the smallest retort obtainable, 
 is unsatisfactory. — W. L. B. 
 J5 
 
2 26 MANUAL OF ASSAYING. 
 
 either the crucible or scorification process, 
 owing to the impossibility of securing an 
 average sample. 
 
 The ore, for supposition, may be of such 
 value that even when put through a lOO-mesh 
 sieve one flake that would go through such 
 a mesh could represent the amount of gold 
 in two assay tons. 
 
 If then of two assay tons of ore of the above 
 character, one is taken, it must run either 
 nothing or double the true value of the ore. 
 
 Again, on low grade ores and with the 
 charge most convenient to employ, the result 
 or weighable button is so small that its esti- 
 mation is liable to error. 
 
 Many ores containing small quantities of 
 gold are frequently profitable to work, as in 
 the case of placers and of large quartz ledges 
 where the rock is soft and gold (fee. In such 
 cases the assay report based upon the small 
 qv-antity of ore used in the scorification, or 
 even in the crucible assay, is unsatisfactory for 
 this and the previous reasons. 
 
APPENDIX. 227 
 
 Here, then, we resort to the pan test, for by 
 it we can treat large amounts of ore, and the 
 greater the quantity operated upon the more 
 reliable the result. 
 
 The pan test is a process of concentration 
 (doing on a small scale that which concentra- 
 tors effect on the large), the product being 
 either gold particles, or gold sulphurets, iron, 
 sand, etc., depending on how far the process 
 is carried. 
 
 The pan itself is a Russia sheet iron vessel 
 of a shallow truncated conical shape (diameter 
 about 16^ inches). That form sold by min- 
 ing outfit establishments has been found 
 most useful in practical operations. A round 
 shallow wooden dish with its bottom sloping 
 to a point, and technically known as a 
 " Batea," is a useful modification (fig. 48 
 of Atwood ; size of batea : diameter, 1 7 inches ; 
 depth, i^ inches; thickness, | inch ; angle of 
 sides, 12°; material, Honduras mahogany). 
 Each person will exercise his own choice after 
 learning the operation. After the requisite 
 
2 28 MANUAL OF ASSAYING. 
 
 skill has been acquired, a pan can be extem- 
 porized from almost any kind of dish, or a 
 section of bullock's horn or an iron spoon 
 may serve as substitutes. 
 
 The requisite amount of ore from loo to 
 500 assay tons (5 to 25 pounds, or in French 
 weights 3 to 15 kilos), depending upon its 
 richness, is sampled, crushed and pulverized 
 as directed in the chapter on gold and silver 
 ore. The pulverization, however, need be 
 carried no finer than to cause the ore to pass 
 through a 40, 50 or 60 mesh sieve (the latter 
 preferred). Weigh now the ore and put in 
 the pan, which latter must be free from 
 grease. Moisten and let it stand for a few 
 moments in order that particles may not float 
 off when the pan is put in water. 
 
 When wet, the whole pan and ore is gently 
 sunk below the surface of a tank of water (a 
 common wash tub will do nicely in the labora- 
 tory). A peculiar oscillatory motion or side 
 vibration is commenced, though not enough 
 to throw any particles of ore over the edges 
 
APPENDIX. 229 
 
 of the pan. The object of this is to settle the 
 heavier particles (the free gold, heavy miner- 
 als, black sand, etc.), and have nothing on the 
 surface but rock or quartz ; a little experience 
 will teach the point. Then slightly incline 
 the pan, and so wash it around as to carry the 
 surface rock over the- edge ; only a little at a 
 • time, however. 
 
 Level the pan and resettle as at first ; again 
 incline and wash. more over the edge. Keep 
 up this operation, gradually getting more and 
 more rock over the edge, and becoming more 
 earef ul and washing . more delicately as the 
 process continues. 
 
 Toward the end of the operation, that is, 
 when the rock is nearly gone, be careful to 
 keep the ore under the surface of the water, 
 as the gold might otherwise become dry and 
 float off. Also make no sudden or unusual 
 lurch, or the whole result may go off the pan. 
 The above manipulation is far more difficult 
 to describe than to perform after having once 
 been acquired. Dry. the residue. 
 
230 MANUAL OF ASSAYING. 
 
 If gold alone is obtained, that is, gold (or 
 gold and silver) free from sulphurets, etc., it 
 must be treated as an alloy, weighed, parted 
 and weighed again, or cupelled with lead, 
 weighed, parted and weighed ; in both cases 
 giving gold and silver. 
 
 If the panning is not carried to such a point 
 as to get rid of all the rock, the concentration 
 is all scorified with test lead (or run down in 
 a crucible), cupelled, parted and weighed. 
 In the case of an ore supposed to carry aurif- 
 erous sulphurets it should be panned so far 
 as can safely be done without losing metallif- 
 erous particles and the concentration treated 
 as above described. 
 
 If the ore is quite poor, or a large quantity 
 is desired to be worked, the panning can be 
 carried on roughly and the successive con- 
 centrations finally panned together. 
 
 The results are based upon the amount of 
 ore taken in the pan. If much of this work 
 was to be done, a set of weights from 500 
 A. T. down (approximately accurate) would 
 
APPENDIX. 231 
 
 be very convenient and save calculation. ' The 
 result would be as many times the number of 
 ounces contained in the ore as the quantity 
 of ore was more than one assay ton. 
 
 For example, the ore was supposed to be 
 very poor and therefore : 
 
 500 A. T. were taken. 
 
 Bead weighed 50 mgrms. 
 
 .'. 500 A. T. : I A. T. : : 50 mgrms. : -^ mgrm., 
 or the ore ran -^ oz. Troy per ton. 
 
 If 100 A. T. had been taken and the same 
 weight bead obtained, we would have : 
 
 100 A. T. : I A. T. :: 50 mgrms. : \ mgrm., 
 or the ore would run \ oz. Troy per ton. 
 
 As an example of the calculation required 
 without the large assay ton weights, I give 
 the following : 
 
 Weight of panful of ore, 2\ kilogrammes=2,2So,ooo 
 
 milligrammes. 
 Weight of bead obtained, gold 20 mgrs., silver 50 mgrs., 
 ^^^^ 2,250.000 mgrms. ..29166 
 
 20 mgrms. x ' " " ' 
 
 2.2SO.OOO mgrms. .. 29166 ^^^^ 
 50 mgrms. x '" " 
 
 The free gold can be separated from the 
 
MAXVAL OF ASSA YING. 
 
 sulphurets (if it be desired to determine how 
 much of the gold is "free" and how much in 
 the "sulphurets") by washing in an amal- 
 gamated pan. Such a vessel may be simply 
 made by bending a piece of thin silver-plated 
 copper (about 6 inches by 12 inches) so as to 
 form curved edges on three sides, the silvered 
 sides in. The side not turned up is one of 
 the narrow ends. A little mercury (free from 
 gold and silver) will quickly amalgamate the 
 interior, and if the ore is washed carefully 
 over this, most of the free gold will become 
 amalgamated and stick to the pan. A piece 
 of chamois skin made into a rubber will push 
 the gold, which can be seen as little specks of 
 amalgam, to the open edge of the pan and 
 into a crucible. The mercury can be driven 
 from the gold by heat. 
 
 No investigation has been made to deter- 
 mine if any silver is carried by the mercury 
 to the assay from the pan, but if such be the 
 fact, the result is still accurate for gold. If 
 carefully performed the results ought to be 
 
APPENDIX. 233 
 
 above the yield from a stamp-mill with amal- • 
 ^amated plates. 
 
 A more^common test than with the above 
 silver-plated amalgamated copper pan, is, after 
 having panned down, to drop a few globules 
 of clean "quicksilver" {i.e., mercury) into 
 the pan and a little cyanide of potassium (to 
 keep the mercury clean). Work up with a 
 spatula till the mercury has taken up the free 
 gold, then collect, and run off the mercury. 
 Clean it and dissolve in nitric acid (for the 
 gold only) or drive off the mercury in the 
 muffle, weigh the residue of gold and silver, 
 part and weigh gold. 
 
 The residue in the pan should then be 
 assayed and the gold and silver (actual 
 weight) determined. Suppose , 
 
 Original weight of ore 2\ kilos. 
 
 Gold and silver after retorting 35 mgrms. 
 
 Gold after parting 15 " 
 
 Hence silver 20 mgrms. 
 
 Gold in sulphurets 50 mgrms. 
 
 Silver " 90 " 
 
234 MANUAL OF ASSA YING. 
 
 Then we have : 
 
 Free gold -^^ oz. per ton of original ore. 
 
 Silver in free gold j^';;- oz. per ton of original 
 ore. 
 
 Gold in sulphurets -^^ oz. per ton of original 
 ore. 
 
 Silver in sulphurets i^^ oz. per ton of origi- 
 nal ore. 
 
 Total gold ^/j oz. per ton of original ore. 
 
 Total silver i-jVir o^- P^"" 'on of original ore. 
 
 There is a certain loss in panning, hence 
 the results are not analytically accurate, but 
 are close indications of the practical result of 
 the working of gold ores in a mill with copper 
 plates.* 
 
 VI. CHLORINATION ASSAY OF GOLD ORES. 
 
 If gold exists free in the gangue, that is, 
 not combined with sulphur, arsenic or tellu- 
 rium, it can be chlorinated directly without 
 roasting. 
 
 * For the information comprised in the above article I am 
 largely indebted to Mr. S. A. Reed of Irwin, Col., and Mr. Ray 
 G. Coates of Chicago, 
 
APPENDIX. 235 
 
 But sulphurets, arseniurets or tellurides 
 must be first roasted and thoroughly at that. 
 
 The chlorination can be done in the labora- 
 tory on either a large or moderately large 
 scale. For the-former, operating say on 20 
 pounds (y^ of a ton), consult the section in 
 Kustel, entitled " Extraction of Gold from 
 Sulphurets, Arseniurets or Quartz, by Chlor- 
 ination," pp. 136-139. 
 
 For the latter grind up 5 to 8 ounces (or 5 
 to 10 A. T.), and, if necessary, roast in the 
 usual manner. Use a frying pan for this 
 purpose, and see that the sulphur is entirely 
 driven out so that no smell (as of a burning 
 'match) is perceptible at the finish. Cool, 
 grind in an iron mortar, and re-roast at a red 
 heat. 
 
 When cold, reserve i A. T. of the ore for 
 regular assay; the remainder is to be chlori- 
 nated in the apparatus herewith described. It 
 consists of a flask, provided with a funnel tube 
 for acid supply and delivery tube for the chlor- 
 ine gas generated. The latter tube dips into 
 
236 MANUAL OF ASSAYING. 
 
 a wash bottle containing water to wash the 
 gas. From the latter the gas passes up into a 
 separatory funnel containing the ore. The 
 exit tube from the funnel may pass into a flue 
 or the open air, or into a cylinder holding 
 shavings moistened with alcohol. 
 
 Place in the flask a mixture of 3 parts of 
 black oxide of manganese, 4 parts of common 
 salt, and 4I parts of water, all well mixed. 
 
 Place the ore, which has been dampened 
 with water, in the separatory funnel, ' having 
 put in at the bottom a very little cotton to 
 prevent the fine ore from stopping the pas- 
 sage of the gas. 
 
 Having now made all ready, pour down 
 through the funnel tube 7^ parts of sulphuric 
 acid at intervals. After a time the flask is to 
 be gently heatqd, that all the chlorine may be 
 driven off. 
 
 Run the operation for about two hours, 
 then disconnect the flask and let the funnel 
 stand over night. Finally take out the upper 
 
APPENDIX. 237 
 
 cork and wash out the chloride of gpld with 
 distilled water. 
 
 To the solution in a beaker or tumbler add 
 a few drops of hydrochloric (muriatic) acid, 
 then some solution in water of sulphate of 
 iron (green vitriol or copperas), stir with a 
 glass rod, warm and let stand undisturbed 
 until all the gold has been thrown down to 
 the bottom and the liquid above is perfectly 
 clear. Half of this liquid is drawn off with a 
 syphon, the remainder containing the gold is 
 filtered as usual, washing with warm water. 
 Dry the filter, burn, scorify ashes and cupel, 
 or cupel directly with sheet lead, weigh, etc. 
 Compare result with unchlorinated sample. 
 Consult Kustel as above, and Ricketts, p. 194. 
 
 VII. CHLORINATION TEST FOR SILVER. 
 
 In smelting-works it is often necessary to 
 test ores that have been subjected to chlorid- 
 izing roasting, to ascertain the amounts of 
 chloride of silver contained in them. Two 
 assays are made of each ore. 
 
238 MANUAL OF ASSAYING. 
 
 Several pounds of the ore are taken from 
 various portions of the enlire lot, well mixed 
 and sifted. From this, weigh out two charges 
 of -^ A. T. Scorify and cupel one charge in 
 the usual manner. 
 
 The other charge is brushed into a filter 
 paper held in a glass funnel, and over it pour 
 a warm solution of hyposulphite of soda (six 
 or eight ounces in a quart of water), which 
 rapidly dissolves the chloride of silver from 
 the ore. Continue this treatment until a 
 small portion of the filtered liquid contained 
 in a test-tube, darkens but slightly and does 
 not lose its transparency upon the addition of 
 a few drops of a solution in water of sulphide 
 of sodium. 
 
 Wash the mass in the filter with warm 
 water, remove filter and all, dry and burn in 
 scorifier in muffle, at a low heat, mix ashes 
 with lead, scorify and cupel as usual. 
 
 (The hyposulphite solution dissolves out 
 sulphate of silver as well as the chloride. If, 
 as is sometimes the case, it is desired to know 
 
APPENDIX. 239 
 
 the amount of sulphate present, leach a third 
 charge with warm water, which will take out 
 the sulphate, but will not touch the chloride 
 or any unacted-upon ore. Scorify and cupel 
 the residue as directed.) 
 
 The difference between the two cupellations 
 shows the amount of silver which has been 
 changed into the state of a chloride. Thus : 
 
 ist charge ran 180 oz. per ton. 
 zd charge ran 10 oz. per ton. 
 Hence, 180—10=170 oz. of chloridized pulp. 
 To obtain percentage : 
 
 180 : 170 :: 100 : x = 94.4 per cent. 
 
 " If there should be gold in the ore, this 
 must be subtracted from .both assays, because, 
 although the amount of gold would be equal, 
 the chlorination result, as it should be, must 
 come out higher after the gold is subtracted." 
 (Kustel.) 
 
 VIII. THE ASSAY OF GOLD BULLION. 
 
 (Consult " Report upon the Wastage of Sil- 
 ver Bullion in the Melter and Refiner's De- 
 
240 MANUAL OF ASSA YING. 
 
 partment of the Mint of the United States, 
 July 25,1872, pp. 60-65, ' The Assay of Gold.' " 
 I am also indebted to Mr. C. Boyer, Assayer 
 of the Branch Mint at Denver, Colo., for valu- 
 able information herein embodied.) 
 
 Secure sample for assay by cutting off a 
 corner of the ingot or bar, which is supposed 
 to be of uniform character. 
 
 Flatten sample on anvil and pass through 
 rolls once or twice, or till the slip is thin 
 enough to be easily cut by shears. 
 
 A special set of weights known as "gold 
 weights" is used in the U. S. Mint and 
 branches. The unit of the system is a " 1000" 
 piece ; from that the .weights range down to a 
 iTToTo" piece. The gold and silver are re- 
 ported in thousandths, that is, in parts of a 
 thousand, hence the use of such weights. The 
 actual weight of each piece in the set of " gold 
 weights " is one-half of its corresponding piece 
 in the French or Metric system, thus the 
 "1000" weight weighs actually 500 mgrms.. 
 and so on. 
 
APPENDIX. 241 
 
 Weigh out very carefully " 1000" of the 
 sample (or 500 mgrms.), and add twice as much 
 pure silver (foil) as there is gold, allowing for 
 the silver assumed to be in the sample. (The 
 fineness of the sample is determined by com- 
 parison with slips of known fineness ; in time 
 the assayer can determine this without such 
 aid.) For example a sample is thought to be 
 900 fine, that is, made up of 900 parts gold 
 and 100 parts silver; total, 1000. Add then 
 1700 parts silver, which with the 100 parts 
 already in the sample will make 1800 or twice 
 the 900 parts of gold. 
 
 If the slip appears to contain very little cop- 
 per add a small piece, say 50 mgrms. Wrap 
 the gold, silver and copper in a piece of pure 
 lead foil of about ten times the weight of the 
 assay ; squeeze all into a bullet. 
 
 Cupel in the usual manner. When all the 
 lead has been cupelled away, remove from 
 muffle, detach button, flatten on anvil, and 
 anneal by heating on an annealing plate in 
 the muffle. Take out, pass through the rolls, 
 
 i6 
 
242 MANUAL OF ASSAYING. 
 
 anneal again and form into a coil known as a 
 cornet. 
 
 Introduce into a parting flask or matrass, 
 one ounce of pure nitric acid of 32" Beaum6 
 (specific gravity 1.26, see page 162), add a 
 pinch of thoroughly charred wood charcoal 
 (see Mitchell, page 165), and heat to boiling 
 on sand bath. Now place the cornet in the 
 matrass, and boil for ten minutes. Pour off, 
 add a second charge of | of an ounce of same 
 strength acid, and boil for ten minutes again. 
 
 Pour off the acid and wash the cornet 
 thoroughly with distilled water. Add a 
 couple of ounces of water to the matrass, 
 place an annealing cup over the top and in- 
 vert ; by this means the cornet is deposited 
 without loss or injury in the cup. Decant out 
 of this the water and heat the cup containing 
 the cornet, at first gently on the sand bath till 
 all the moisture has been driven off, then in 
 the muffle, making the third time of annealing. 
 
 Weigh the cornet, using the gold weights 
 (or the gramme weights and multiplying by 
 
APPENDIX. 243 
 
 two). The result will be the amount of gold 
 in the bullion or the fineness. 
 
 By subjecting another " 1000" of the sam- 
 ple to cupellation wiikout silver, the base 
 metal is oxidized off, leaving the gold and 
 silver on the cupel. " The loss gives the pro- 
 portion of base metal and the difference be- 
 tween the "1000" (the original weight) and the 
 sum of the fineness of the gold and the 
 amount of base metal will be the amount of 
 silver in the alloy." 
 
 IX. THE ASSAY OF BASE BULLION. 
 
 The uncertainty in the assay of base bullion 
 lies, not in the determination of the amounts 
 of gold and silver present, but in the difficulty 
 of obtaining an average sample. 
 
 This question has given rise to an amicable 
 discussion in the columns of the Engineering 
 and Mining Journal, between various parties 
 interested (issues of May 20, June 3, July i, 
 and Sept. 9, 1882), eliciting some valuable 
 information which I purpose to reproduce 
 herewith. 
 
244 MANUAL OF ASSA YING. 
 
 A base bullion may contain lead, silver, 
 gold, copper, arsenic, antimony, and perhaps 
 other metals, and sulphur. When this is 
 melted and cooled, it tends to form alloys of 
 varying degrees of fusibility, which with the 
 dross or scum (a mixture of oxides, sulphides, 
 etc.) make a pig or bar from which it is not 
 an easy matter to select a fair sample for 
 assay. 
 
 In many smelting establishments the sur- 
 face of the melted bullion is skimmed, and 
 the clear lead ladled into the mould, till the 
 latter is filled to within an inch of the top, 
 and when it has solidified, the mould is filled 
 completely. There results then a nice-look- 
 ing bar, composed of good lead above and 
 below, with much dross in the centre. This 
 would not matter so much if an equal portion 
 of the dross could be gotten at, for assay, but 
 there's the rub. The ordinary way of chip- 
 ping the top and bottom of the bar does no 
 good, since it seldom cuts deeper than \ inch 
 below the surface. Even a punch cutting a 
 
APPENDIX. 245 
 
 chip f inch deep does not solve the problem, 
 for it will not reach the dross when cast in the 
 middle of the bar. 
 
 Mr. L. S. Austin in the issue of Sept. 9 of 
 the journal quoted suggests a method which 
 seems to meet the requirement. " It consists 
 in the use of the punch which I have already 
 described, [June 3d issue] and which takes 
 a chip of about \ inch in diameter and uni- 
 form in thickness. It is driven clear in to 
 one-half the depth of the bar by the use of a 
 sledge.- The bar being, say four inches in 
 depth, a chip a little over two inches long is 
 then taken both from top and bottom of the 
 bar. The chip is then slipped into a hole 
 bored two inches deep into a block, and the 
 projecting lower end trimmed off with shears 
 to the exact length of two inches. Each 
 chip represents consequently one-half the bar, 
 its companion representing the other half; 
 moreover, each chip is of the same weight. 
 Thus each bar is represented according to its 
 relative weight and to its entire depth." 
 
246 MANUAL OF ASSAYING. 
 
 Having obtained these chips, they are next 
 melted, and poured into a small mould. Take 
 this sample bar, cut slices across, each slice 
 being a section of the bar. Cut from these 
 slices \ A. T. for assay. By running five of 
 these -^ A. T. assays, and uniting the silver 
 beads obtained, for parting, the gold present 
 can be accurately determined. 
 
 Cupel the samples, "feathering" the 
 cupels. Brittle or hard bullion can be scori- 
 fied first, if necessary. 
 
 Consult , the numbers of the journal 
 referred to. 
 
 X. COLOR TESTS. 
 
 Scarification. — During the first part of the 
 process of scorification of ores that have not 
 been roasted or only partially so, the colors of 
 the fumes given off will often indicate the 
 nature of the ore. 
 
 Thus sulphur emits clear gray vapors ; zinc, 
 blackish vapors, and a brilliant white flame ; 
 arsenic, whitish-gray vapors ; and antimony, 
 fine red vapors (Mitchell). 
 
APPENDIX. 247 
 
 Scarifiers. — The colors shown by the interi- 
 ors of scorifiers after scorification are often 
 characteristic. 
 
 Lead tends to color the scorifier a lemon- 
 yellow. 
 
 Iron colors it in various shades of reddish- 
 brown, from a brick-red to a deep rich mahog- 
 any. 
 
 Copper, according to its percentage, gives a 
 green, ranging from light to very dark. 
 
 Tellurium colors the scorifier a deep blood- 
 red. 
 
 Combinations of the metals are liable to 
 influence these colors, and produce mixed 
 shades. 
 
 Cupels. — The color and appearance of a 
 cupel are occasionally indices of the metals 
 present in the ore. 
 Antimony : Litharge-yellow to brownish-red 
 
 scoriae, cupel often cracks (Mitchell). 
 Arsenic : White or pale yellow scoriae (Trip- 
 
 lett). 
 Bismuth : An orange-yellow color (North). 
 
248 MANUAL OF ASSAYING. 
 
 Chromium : Dark brick-red stain (Triplett). 
 
 Cobalt : Dark green scoriae ; greenish stain 
 (Triplett). 
 
 Copper : Dark purplish-black stain, some- 
 times with a greenish cast or even a 
 brown, at times a gray or dirty red ; the 
 edges show a purplish-red tint ; there is 
 generally a rose coat on the outside of 
 cupels from ores rich in copper, which 
 need not be mistaken for the rose color 
 of oxide of silver. 
 
 Iron : From light through dark brown to 
 almost black ; corroded rings on cupel. 
 
 Lead . Lemon-yellow, straw or orange-yellow. 
 
 Manganese : Dark bluish-black stain ; cupel 
 corroded (Triplett). 
 
 Palladium and Platinum : Greenish stains and 
 crystalline buttons (Triplett). 
 
 Tin : Gray scoriae. 
 
 Zinc : Yellowish ring on cupel, often causes 
 loss of silver by ebullition ; flame very 
 luminous. 
 
APPENDIX. 249 
 
 XI. QUALITATIVE TESTS. 
 
 I have thought it a good plan to give a few 
 siipple wet tests for some of the metals, and 
 acids united with them, as found in ores. 
 
 Ordinarily these tests work better on the 
 powdered ore, though sometimes, as will be 
 mentioned, the original rock can be directly- 
 treated. 
 
 Carbonates i — Place a drop of any strong 
 acid upon the suspected rock ; if effervescence 
 (or boiling up) ensues, unaccompanied by 
 any odor, it contains carbonates. This test 
 does not always show well with small quanti- 
 ties of carbonates ; try then some of the 
 powdered ore with acid in a test-tube. To 
 confirm the presence of carbonic acid, suspend 
 in the test-tube a glass rod that has previously 
 been dipped in lime-water ; the . drop on the 
 rod should become turbid or milky, owing to 
 the formation of carbonate of lime. 
 
 Place a small sample of the pulverized ore 
 in a test-tube, add to it some nitric acid, a 
 little more than will cover it, and heat till the 
 
250 MANUAL OF ASSAYING. 
 
 acid does not seem to dissolve any more of 
 the ore ; let cool, after which add as much 
 pure water as there is acid, and shake. 
 
 Filter, in manner described under "Copper 
 Analysis," p. 212. 
 
 Sulphates. — To some of the filtered acid 
 solution add solution of chloride of barium 
 (or, if lead be present, of nitrate of barium). 
 A white cloudiness or precipitate (which does 
 not instantly form in dilute solutions) shows 
 the presence of sulphates. 
 
 Sulphides. — To a piece of the rock, or to 
 some of the powdered ore, add a drop of 
 nitric acid. If sulphides are present in any 
 quantity, a strong odor, similar to that of rot- 
 ten eggs, will be given off. 
 
 Telliirides. — Take a small piece of the ore 
 and place it on the cover of a porcelain cap- 
 sule, and heat with the inner flame of the 
 blow-pipe for a couple of minutes. Now place 
 a drop of concentrated sulphuric acid on the 
 cover, and let it slide down to the heated 
 fragment. As soon as it touches or ap- 
 
APPENDIX. 251 
 
 proaches very near the ore a beautiful carmine 
 coloration forms, strongly contrasting with the 
 white porcelain. As the latter cools, the 
 color fades. Any white crockery, as a piece 
 of a broken plate or saucer, will do to use in 
 this test. 
 
 Copper. — To a piece of. the rock on a white 
 porcelain surface add a few drops of nitric 
 acid and stir. Add now an excess of ammo- 
 nia water. If the mass turns blue, copper or 
 its compounds is undoubtedly in the ore. If 
 the latter contains much copper, a polished 
 knife-blade dipped in an acid solution of it 
 will receive a coating of metallic copper. 
 
 Iron. — If, at the same time tjie solu^on 
 treated with ammonia turns blue, or even if it 
 does not do so, there appears on the 'porce- 
 lain or in the test-tube, a reddish-brown gelat- 
 inous mass, then iron is present. 
 
 As further tests for iron, on one part of an 
 old plate put a crystal of sulphocyanide of 
 potassium and on another a lump of ferrocya- 
 nide of potassium (yellow prussiate of potash); 
 
252 MANUAL OF ASSAYING. 
 
 now pour on each a little of a hydrochloric acid 
 solution of an ore containing iron ; a blood-red 
 coloration with the first-named re-agent, and a 
 magnificent blue precipitate with the second, 
 prove conclusively the presence of iron com- 
 pounds. Of course these tests can be shown 
 with the filtered solution in test-tubes. 
 
 Lead. — Drop a little nitric acid upon a piece 
 of ore supposed to contain lead, then add a 
 little water, and finally a crystal of iodide of 
 potassium. A bright-yellow precipitate will 
 form if lead is present. 
 
 Silver. — If this metal is in any appreciable 
 quantity in an ore, it will dissolve in nitric 
 aci4 (excepting the chloride ores). To the 
 acid solution, add a little hydrochloric acid, 
 solution of common salt, or even a dry grain 
 or two of the latter. A curdy, white precipi- 
 tate of chloride of silver is thrown down, 
 which is not soluble in water (as is chloride 
 of lead on the contrary), but dissolves easily 
 in ammonia water. The precipitate turns 
 black on being exposed to light. 
 
APPENDIX. 253 
 
 As Stated above, chloride ores do not dis- 
 solve in nitric acid ; therefore when they are 
 suspected to be present, put some of the 
 powdered ore into a small bottle, pour in a 
 small quantity of very strong ammonia water, 
 cork up the bottle and let it stand for a few 
 hours. Then add, in slight excess, nitric 
 acid. The white precipitate of silver chloride 
 will at once come down if there is any in the 
 ore. 
 
 The best test for gold is the fire assay. To 
 
 learn the colors and appearances of the tests 
 
 above given, try them on the following 
 
 substances: 
 
 Carbonates Bi-carbonate of Soda. 
 
 Chlorides Common Salt. 
 
 Sulphates Sulphuric Acid. 
 
 Sulphides Copper or Iron Pyrites. 
 
 Tellurides Any Telluride Ore. 
 
 Copper Copper Wire. 
 
 Iron Nail or Wire. 
 
 Lead Sheet Lead or Galena. 
 
 Silver Silver Foil and Horn Silver. 
 
 Consult the books on qualitative analysis 
 for further information or tests. 
 
254 MANUAL OF ASSAYING. 
 
 XII. BRIEF SCHEME FOR SILICA, IRON AND 
 
 MANGANESE. 
 
 It is very often the case that the percent- 
 ages in an ore of the above mentioned sub- 
 stances are wanted. More particularly is 
 this true with carbonate ores. Hence the 
 following notes: 
 
 Dissolve the weighed ore in hydrochloric 
 acid by the aid of heat. Filter hot and wash 
 with hot water. The filtrate contains the 
 iron, with chloride of lead, etc. 
 
 The silica on filter contains chloride of 
 lead. Wash this out with hot solution of 
 citrate of ammonium, following with hot 
 water. Ignite the silica while still damp. 
 
 To the iron in solution in the filtrate, add 
 sufficient sulphuric acid to convert all the 
 lead into sulphate of lead. Warm the solu- 
 tion if not already so, and add, drop by drop, 
 dilute stannous chloride solution, until the 
 liquid becomes colorless, showing that the iron 
 is all reduced to state of protoxide. Avoid a 
 great excess of the tin solution. Now cool, 
 
APPENDIX. 255 
 
 and add, all at once, an excess of strong mer- 
 curic chloride solution. The precipitate 
 formed should be perfectly white. If dark 
 colored, it indicates that insufficient mercuric 
 chloride has been used, and the analysis is 
 spoiled. If the precipitate is all right, the 
 solution is ready for titration with standard 
 bi-chromate of potash solution. (Consult 
 Fresenius' "Qualitative and Quantitative 
 Analysis," and Hart and Sutton on "Vol- 
 umetric Analysis.") 
 
 For manganese in ores (excepting sili- 
 cates), heat a weighed sample in crucible in 
 open fire for fifteen minutes, converting the 
 manganese into protosesquioxide of man- 
 ganese. Treat with hydrochloric acid, and 
 titrate with iodide of potassium and hyposul- 
 phite of sodium. (See Sutton.) 
 
 XIII. DETERMINATION OF MOISTURE IN AN ORE. 
 
 It is often a matter of importance to know 
 the amount of moisture or water contained in 
 an ore. The simplest manner in which to 
 
256 MANUAL OF ASSAYING. 
 
 determine this, and a satisfactory one at that, 
 is to sample out a certain weight, say five 
 grammes, and transfer to a porcelain capsule, 
 the weight of which is already known. 
 Expose the capsule and contents to steam- 
 heat in any convenient way, for one-half hour, 
 then weigh. Heat half an hour longer and 
 weigh again. There should be but a slight 
 difference in the last two weighings. The 
 difference between the last weight and the 
 original weight of dish and ore, is the loss by 
 driving off the water; this difference divided 
 by the amount of ore taken, and multiplied 
 by 100, is the percentage of moisture in the 
 ore. 
 
SECTION II. 
 
 LISTS AND REFERENCES. 
 GOLD. 
 
 LIST OF THE PRINCIPAL GOLD MINERALS FOUND IN THE 
 UNITED STATES. 
 
 NAME. 
 
 1. Calaverite (telluride of gold). 
 
 2. Gold amalgam. 
 
 3. Electrum (argentiferous gold). 
 
 4. Miillerite (telluride of gold, 
 silver and lead). 
 
 5. Nagyagite (black tellurium, 
 foliated tellurium, telluride 
 of gold and lead). 
 
 6. Native gold (flour, leaf, wire, 
 nugget, free, etc.). 
 
 7. Petzite (telluride of gold and 
 silver). 
 
 8. Sylvanite (graphic tellurium, 
 
 yellow tellurium, telluride of 
 
 gold and silver) 
 
 17 257 
 
 COMPOSITION. 
 
 Gold, tellurium. 
 
 Gold, mercury. 
 
 Gold, silver. 
 
 Gold, silver," lead, 
 tellurium. 
 
 Gold, lead, tellu- 
 rium (anti^mony, 
 sulphur). 
 
 Gold. 
 
 Gold, silver, tellu- 
 rium. 
 
 Gold, silver, tellu- 
 rium (antimony). 
 
258 
 
 MANUAL OF ASSAYING. 
 
 
 MINERALS LIKELY TO 
 
 CARRY GOLD. 
 
 I. 
 
 Aikinite. 
 
 14. 
 
 Magnolite. 
 
 2. 
 
 Altaite. 
 
 IS- 
 
 Melaconite. 
 
 3- 
 
 Argentite. 
 
 16. 
 
 Native arsenic. 
 
 4- 
 
 Arsenopyrite. 
 
 17- 
 
 " bismuth. 
 
 5- 
 
 Bismuthinite. 
 
 18. 
 
 " silver. 
 
 6. 
 
 Chalcopyrite. 
 
 19. 
 
 " tellurium. 
 
 7- 
 
 Coloradoite. 
 
 20.' 
 
 Pyrite. 
 
 8. 
 
 Ferro-tellurite 
 
 21. 
 
 Sphalerite. 
 
 9- 
 
 Galen ite. 
 
 22. 
 
 Tellurite. 
 
 lO. 
 
 Henryite. 
 
 23- 
 
 Tellurpyrite. 
 
 II. 
 
 Hessite. 
 
 24. 
 
 Tetradymite. 
 
 12. 
 
 Joseite. 
 
 25- 
 
 Tetrahedrite. 
 
 13- 
 
 Lionite. 
 
 26. 
 
 Wehrlite. 
 
 SILVER. 
 
 LIST OF THE PRINCIPAL SILVER MINERALS FOUND IN 
 THE UNITED STATES. 
 NAME. COMPOSITION. 
 
 1. Alaskaite (sulphide of bis- 
 muth, silver and lead). 
 
 2. Argentite (sulphuret or sul- 
 phide of silver, vitreous silver, 
 silver gla;nce). 
 
 3. Bromyrite (bromide of silver, 
 bromic silver). 
 
 Silver, bismuth, 
 lead, copper, sul- 
 phur. 
 
 Silver, sulphur. 
 
 Silver, bromine. 
 
APPENDIX. 259 
 
 4. Cerargyrite (muriate or chlo- Silver, chlorine, 
 ride of silver, horn-silver) 
 
 5. Dyscrasite (antirnonial sil- Silver, antirnony. 
 ver). 
 
 6. Electrum (argentiferous Silver, gold, 
 gold). 
 
 7. Embolite (chloro-bromide of Silver, chlorine, 
 silver). bromine. 
 
 S. Freieslebenite (antirnonial Silver, lead, anti- 
 sulphide of silver and lead). mony, sulphur. 
 
 9. Hessite (telluride of silver, Silver, tellurium, 
 telluric silver). 
 
 10. lodyrite (iodide of silver, Silver, iodine, 
 iodic silver). 
 
 11. Miargyrite (sulphide or sul- Silver, antimony, 
 phuret of silver and antimony) sulphur. 
 
 12. Native silver (free, wire, leaf. Silver, 
 dendritic, etc.). 
 
 13. Petzite (telluride of silver and Silver, gold, tellu- 
 gold). rium. 
 
 14. Polybasite (sulphide of silver. Silver, antimony, 
 antimony and arsenic). arsenic, copper, 
 
 sulphur. 
 
 15. Proustite(arsenicalsilverore, Silver, arsenic, sul- 
 light red silver ore, ruby sil- phur. 
 
 ver). 
 
26o 
 
 MANUAL OF ASSAYING. 
 
 i6. Pyrargyrite (antimonial red 
 silver ore, dark red silver ore, 
 ruby silver). 
 
 17. Schapbachite (bismuth -sil- 
 ver, sulphide of bismuth, sil- 
 ver and lead). 
 
 18. Schirmerite (same as above 
 but proportions varying). 
 
 19. Stephanite (sulphide of silver 
 and antimony, brittle silver, 
 black silver). 
 
 20. Sternbergite (sulphide of sil- 
 ver and iron). 
 
 21. Stetefeldite (oxide of anti- 
 mony with silver, etc.). 
 
 22. Stromeyerite (sulphide or sul- 
 phuret of silver and copper, 
 silver-copper glance). 
 
 23. Sylvanite (graphic tellurium, 
 yellow tellurium, telluride of 
 silver and gold). 
 
 24. Tetrahedrite (gray copper 
 ore, sulphide of copper, anti- 
 mony, silver, etc.). 
 
 Silver, antimony, 
 sulphur. 
 
 Silver, bismuth, 
 lead, sulphur. 
 
 Silver, bismuth, 
 lead, sulphur. 
 
 Silver, antimony, 
 sulphur. 
 
 Silver, iron, sul- 
 phur. 
 
 Silver, antimony, 
 copper, oxygen, 
 sulphur. 
 
 Silver, copper, sul- 
 phur. 
 
 Silver, gold, tellu- 
 rium (antimony). 
 
 Silver, copper, an- 
 timony, sulphur 
 (arseniCjbismuth, 
 mercury, zinc, 
 etc.) 
 
APPENDIX. 
 
 261 
 
 
 MINERALS LIKELY 
 
 TO CARRY SILVER. 
 
 I. 
 
 Algodonite. 
 
 22. 
 
 Melaconite. 
 
 2. 
 
 Altaite. 
 
 23- 
 
 Miillerite. 
 
 3- 
 
 Arsenopyrite. 
 
 24. 
 
 Nagyagite. 
 
 4- 
 
 Barnhardite. 
 
 25- 
 
 Native antimony. 
 
 S- 
 
 Bornite. 
 
 26 
 
 " arsenic. 
 
 6. 
 
 Boulangerite. 
 
 27. 
 
 " bismuth. 
 
 7- 
 
 Calaverite. 
 
 28. 
 
 " copper. 
 
 8. 
 
 Cerussite. 
 
 29. 
 
 " gold. 
 
 9- 
 
 Chalcopyrite. 
 
 3°- 
 
 " mercury. 
 
 10. 
 
 Coloradoite. ■ 
 
 31- 
 
 " tellurium 
 
 II. 
 
 • 
 Enargite. 
 
 32- 
 
 Petzite. 
 
 12. 
 
 Ferro-tellurite. 
 
 33- 
 
 Pyrite. 
 
 13- 
 
 Gilenite. 
 
 34. 
 
 Realgar. 
 
 14- 
 
 Geocronite. 
 
 35- 
 
 Smaltite. 
 
 15- 
 
 Gold amalgam. 
 
 36- 
 
 Sphalerite. 
 
 16. 
 
 Henryite. 
 
 37- 
 
 Sylvanite. 
 
 17- 
 
 Hessite. 
 
 38. 
 
 Tellurite. 
 
 18. 
 
 Joseite. 
 
 39- 
 
 Tellurpyrite. 
 
 19. 
 
 Leucopyrites. 
 
 40. 
 
 Tetradymite. 
 
 20. 
 
 Lionite. 
 
 41- 
 
 Wehrlite. 
 
 21. 
 
 Magnolite. 
 
 
 
262 
 
 MANUAL OF ASSA YING. 
 
 COPPER. 
 
 LIST OF THE PRINCIPAL COPPER MINERALS FOUND IN 
 THE UNITED STATES. 
 
 NAME. 
 
 1. Aikinite (needle ore, acicular 
 bismuth, cupreous bismuth). 
 
 2. Algodonite (arsenide of cop- 
 per). 
 
 3. Atacamite (muriate of cop- 
 per, oxy-chloride of copper). 
 
 4. Aurichalcite (carbonate of 
 zinc and copper). 
 
 5. Azurite (mountain blue, blue 
 carbonate of copper, blue 
 malachite, azure copper ore). 
 
 6. Barnhardite (sulphide of iron 
 and copper). 
 
 7. Bornite (purple copper ore, 
 variegated copper ore, erubes- 
 cite, sulphide of copper and 
 iron). 
 
 8. Bournonite (triple sulphuret 
 of copper, lead and antimony). 
 
 9. Brochantite (sulphate of cop- 
 per). 
 
 COMPOSITION. 
 
 Copper, bismuth, 
 
 lead, sulphur. 
 Copper, arsenic. 
 
 Copper, chlorine, 
 oxygen (water). 
 
 Copptr, zinc, car- 
 bon, oxygen 
 (water). 
 
 Copper, carbon, 
 oxygen (water). 
 
 Copper, iron, sul- 
 phur. 
 
 Copper, iron, sul- 
 phur. 
 
 Copper, lead, anti- 
 mony, sulphur. 
 
 Copper, oxygen, 
 sulphur (water). 
 
APPENDIX. 263 
 
 10. Caledonite (cupreous sul- Copper, lead, car- 
 phato-carbonate of lead). bon, oxygen, sul- 
 phur. 
 
 11. Carrollite (sulphide of cobaflt Copper, cobalt 
 (nickel) and copper). (nickel), sulphur. 
 
 12. Chalcanthite (blue vitriol, Copper, oxygen, 
 copper vitriol, sulphate of sulphur (water), 
 copper). 
 
 13. Chalcocite (copper glance, Copper, sulphur, 
 vitreous copper, sulphuret or 
 
 sulphide of copper). 
 
 14. Chalcopyrite (copper pyrites, Copper, iron, sul- 
 pyritous copper, sulphide of phur. 
 
 copper and iron). 
 
 15. Chrysocolla(mountain green, Copper, silicon, ox- 
 mountain blue, silicate of cop- ygen (water), 
 per). 
 
 16. Covellite (indigo copper, blue Copper, sulphur, 
 copper, sulphide of copper). 
 
 17. Cuprite (red oxide of copper, Copper, oxygen, 
 cupreous oxide). 
 
 18. Domeykite (arsenical copper. Copper, arsenic, 
 arsenide of copper). 
 
 19. Enargite (sulph-arsenite of Copper, arsenic,sul- 
 copper). phur. 
 
 20. Harrisite(sulphide of copper) Copper, sulphur. 
 
264 
 
 MANUAL OF ASSAYING. 
 
 21. Malachite (mountain green, 
 green carbonate of copper, 
 green malachite,greencopper). 
 
 22. Melaconite (black oxide of 
 copper, black copper, cupric 
 oxide). 
 
 23. Native copper (sometimes 
 with silver). 
 
 24. Pseudomalachite (phosphate 
 of copper). 
 
 25. Stromeyerite (sulphuret of 
 silver and copper, silver-cop- 
 per glance). 
 
 26. Tennantite (sulph-arsenite of 
 copper). 
 
 27. Tetrahedrite (gray copper 
 ore, sulphide of copper and 
 antimony with various other 
 sulphides). 
 
 28. Torbernite (copper-uranite, 
 phosphate of uranium and 
 copper). 
 
 29. Uranochalcite (oxide of uran- 
 ium with oxide of copper and 
 sulphate of lime) 
 
 Copper, carbon, ox- 
 ygen (water). 
 
 Copper, oxygen. 
 
 Copper (silver). 
 
 Copper, oxygen, 
 phosphorus 
 (water). 
 
 Copper, silver, sul- 
 phur. 
 
 Copper, arsenic, 
 sulphur (iron). 
 
 Copper, antimony, 
 sulphur (arsenic, 
 bisrnuth, silver, 
 mercury, zinc.etc) 
 
 Copperj uranium, 
 phosphorus, ox- 
 ygen (water). 
 
 Copper, uranium, 
 oxygen, sulphur, 
 calcium (water). 
 
APPENDIX. 
 
 265 
 
 30. Vanquelinite (chromate of Copper, lead, chro- 
 copper and lead). mium, oxygen. 
 
 31. Whitneyite (arsenide of cop- Copp.er, arsenic, 
 per). 
 
 LEAD. 
 
 LIST OF THE PRINCIPAL LEAD MINERALS FOUND IN THE 
 UNITED STATES. 
 NAME. COMPOSITION. 
 
 1. Alaskaite (sulphide of bis- 
 muth, silver and lead). 
 
 2. Altaite (telluride of lead). 
 
 3. Anglesite (lead-vitriol, sul- 
 phate of lead). 
 
 4. Boulangerite (sulphide of 
 lead and antimony). 
 
 S Bournonite (triple sulphuret 
 of copper, lead and antimony). 
 
 6. Caledonite (cup reous-sul- 
 phato-carbonate of lead). 
 
 t 
 
 7. Cerussite (white lead ore, 
 carbonate of lead). 
 
 8. Dechenite (vanadate of lead 
 and zinc). 
 
 9. Descloizite (vanadate of 
 lead). 
 
 Lead, bismuth, sil- 
 ver, copper, sul- 
 phur. 
 
 Lead, tellurium. 
 
 Lead, oxygen, sul- 
 phur. 
 
 Lead, antimony, 
 sulphur. 
 
 Lead, copper, anti- 
 mony, sulphur. 
 
 Lead, carbon, cop- 
 per, oxygen, sul- 
 phur. 
 
 Lead, carbon, oxy- 
 gen. 
 
 Lead, vanadium, 
 zinc, oxygen. 
 
 Lead, vanadium, 
 oxygen. 
 
266 
 
 MANUAL OF ASSA YING. 
 
 10. Freieslebenite (antimonial 
 sulphide of silver and lead). 
 
 11. Galenite (galena, sulphide or 
 sulphuret of lead). 
 
 12. Geocronite (sulph-arseno-an- 
 timonite of lead). 
 
 13. Henryite (telluride of lead, 
 with a little iron). 
 
 14. Jamesonite (sulph-antimon- 
 ite of lead). 
 
 15. Kobellite (sulphide of lead, 
 bismuth and antimony). 
 
 1 6. Lanarkite (sulphato-carbon- 
 ate of lead). 
 
 17. Leadhillite (sulphato-tri-car- 
 bonate of lead). 
 
 18. Massicot (plumbic ochre, 
 yellow oxide of lead). 
 
 19. Mimetite (green lead ore, 
 arsenate of lead). 
 
 20. Minium (red oxide of lead). 
 
 21. Miillerite (telluride of gold, 
 silver and lead). 
 
 Lead, silver, anti- 
 mony, sulphur. 
 Lead, sulphur. 
 
 Lead, antimony,, 
 arsenic, sulphur. 
 
 Lead, tellurium,, 
 iron. 
 
 Lead, antimony, 
 sulphur (iron). 
 
 Lead, bismuth, an- 
 timony, sulphur. 
 
 Lead, carbon, oxy- 
 gen, sulphur. 
 
 Lead, carbon, oxy- 
 gen, sulphur. 
 
 Lead, i part; oxy- 
 gen, I part. 
 
 Lead, arsenic, oxy- 
 gen (chlorine,, 
 phosphorus). 
 
 Lead, 3 parts; oxy- 
 gen, 4 parts. 
 
 Lead, gold, silver, 
 tellurium. 
 
APPENDIX. 
 
 267 
 
 22. Nagyagite (black tellurium, 
 foliated tellurium, telluride of 
 gold and lead). 
 
 23. Native lead. 
 
 24. Plumbogummite (phosphate 
 of alumina and lead). 
 
 25. Pyromorphite (phosphate 
 and chloride of lead). 
 
 26. Schapbachite (bismuth-sil- 
 ver, sulphide of bismuth, sil- 
 ver and lead). 
 
 27. Schirmerite (same as above 
 but proportions varying). 
 
 28. Stolzite (tungstate of lead). 
 
 29. Vanquelinite (chromate of 
 copper and lead). 
 
 30. Wulfenite (yellow lead ore, 
 yellow lead-spar, molybdate 
 of lead). 
 
 Lead, gold, tellu- 
 rium (antimony, 
 sulphur).. 
 
 Lead. 
 
 Lead, aluminum, 
 oxygen, phos- 
 phorus. 
 
 Lead, phosphorus, 
 oxygen, chlorine. 
 
 Lead, bismuth, sil- 
 ver, sulphur. 
 
 Lead, bismuth, sil- 
 ver, sulphur. 
 
 Lead, tungsten, ox- 
 ygen. 
 
 Lead, copper, chro- 
 mium, oxygen. 
 
 Lead,molybdenum, 
 oxygen. 
 
 Note. — For descriptions of the above, and of other American 
 and foreign minerals of gold, silver, copper and lead, consult 
 Dana's System of Mineralogy, 5th Ed. with Sup., and Prof. J. 
 Alden Smith's Report as State Geologist of Colorado, for 1880. 
 
268 MANUAL OF ASSA YING. 
 
 LIST OF USEFUL BOOKS ON SUBJECTS MORE OR LESS 
 CONNECTED WITH ASSAYING. 
 
 General Science. 
 Johnson s New Universal Cyclopaedia. 4 vols. Vols, i 
 and 2, 1876; vol. 3, 1877; vol. 4, 1878. New York. 
 
 General Chemistry. 
 Watts, H.: A Dictionary of Chemistry. 10 vols. Vols. 
 1-6, 1868; ist sup., 1872; 2d sup. (vol. 7), 1875; 3d 
 sup. (vol. 8), Part I, 1879; Part II, 1881. London. 
 
 Chemical Technology. 
 Wagner, R. : A Hand-book of Chemical Technology. 
 Translated from 8th German edition by William 
 Crookes. New York, 1872. 
 
 Reference Books on Chetnistry. 
 
 Roscoe, H. E., and C. Schorlemmer : A Treatise on Chem- 
 istry. 2 vols. Vol. I, The Non-Metallic Elements, 
 1878; vol. 2, Metals, Parts I and II, 1879. New 
 York. 
 
 Miller, W. A. : Elements of Chemistry, Theoretical 
 and Practical. 3 vols. 6th edition. London, 
 1877-1880. 
 
 Text-books on Theoretical Chemistry. 
 Barker, Geo. F. : A Text-book of Elementary Chemis- 
 try, Theoretical and Inorganic. Louisville. 
 
APPENDIX. 269 
 
 Roscoe H. E. : Lessons in Elementary Chemistry, In- 
 organic and Organic. New edition. London, 1880. 
 
 General Qualitative Analysis. 
 
 Fresenius, C.R. : Manual of Qualitative Chemical Anal- 
 ysis. 9th English edition. London, 1876. 
 
 Douglas, S. If., and A. B. Prescott : Qualitative Chem- 
 ical Analysis. 3d edition. New York, 1880. 
 
 Eliot, C. W., and F. H. Storer : A Compendious Man- 
 ual of Qualitative Chemical Analysis. New York, 
 1879. 
 
 General Quantitative Analysis. 
 
 Fresenius, C. J?.: Manual of Quantitative Chemical 
 Analysis. 7th English edition. London, 1876. 
 
 Classen, A.. Elementary Quantitative Analysis. Trans- 
 lated by E. F. Smith. Phila., 1878. 
 
 Cairns, F. A.: A Manual of Quantitative Chemical 
 Analysis for the Use of Students. New York, 
 1880. 
 
 Special* Quantitative Analysis. 
 Rammelsberg, C: Guide to a Course of Quantitative 
 
 Chemical Analysis, especially of Alloys, Minerals 
 
 and Furnace Products. Translated by J. Towler. 
 
 New York, 1872. 
 Wohler, F.: Hand-book of Mineral Analysis. Phila., 
 
 1870. 
 
270 MANUAL OF ASSAYING. 
 
 Volumetric Analysis. 
 Sutton, F.: A Systematic Hand-book of Volumetric 
 
 Analysis. 4th edition. London, 1882. 
 Hart, Edward : A Hand-book of Volumetric Analysis. 
 
 New York, 1878.- 
 
 Laboratory Manipulation. 
 
 Morfit {Campbell and Clarence') : Chemical and Phar- 
 maceutical Manipulations. Phila., 1857. 
 
 Williams, C. G.: A Hand-book of Chemical Manipula- 
 tion. London, 1857; supplement, 1879. 
 
 Geology. 
 Cotta, Bernh. v. Treatise on Ore Deposits. Translated 
 
 from 2d German edition by F. Prime, and revised 
 
 by author. New York, 1870. 
 Dana, J. D.: A Text-book of Geology. 2d edition. 
 
 New York, 1874. 
 Dana, J. D.: Manual of Geology. New York, 1881. 
 Ze Conte, Joseph : Elements of Geology. A text-book 
 
 for colleges and for the general reader. New York, 
 
 1878. 
 Rutley, C. L.: The Study of Rocks. 2d edition. New 
 
 York, 1880. 
 
 Mineralogy. 
 
 Dana, J. D.. A System of Mineralogy. Sth edition, 
 1868; Appendix I, 1872; Appendix II, 1875; Ap- 
 pendix III, 1882. New York. 
 
APPENDIX. 2 7 1 
 
 Dana, J. D.: Manual of Mineralogy and Lithology. 
 3d edition. New York, 1878. 
 
 Brush, G. J.. Manual of Determinative Mineralogy, 
 with an Introduction on " Blow-pipe Analysis." 
 New York, 1878. 
 
 Foye, J. C: Tables for the Determination, Description 
 and Classification of Minerals. Chicago, 1882. 
 
 Frazer, P.: Tables for the Determination of Minerals. 
 Phila., 1874. 
 
 Blow -Pipe Analysis. 
 
 Planner's Manual of Qualitative and Quantitative Anal- 
 ysis with the Blow-pipe. Translated by H. B. 
 Cornwall. 2d edition. New York, 1873. 
 
 Cornwall, H. B.: Manual of Blow-pipe Analysis, Qual- 
 itative and Quantitative. With a Complete Sys- 
 tem of Determinative Mineralogy. New York, 
 1882. 
 
 Attwood, Geo.: Practical Blow-pipe Assaying. New 
 York, 1881. 
 
 Blympton, G. W.: The Blow-pipe. A Guide to its Use 
 in the Determination of Salts and Minerals. New 
 York, 1874. 
 
 -Elderhorsf, Wm.: Manual of Qualitative Blow-pipe 
 Analysis. Revised by H. B. Nason. Phila., 1881. 
 
 Metallurgy and Mining. 
 Kerl, Prof.: Practical Treatise on Metallurgy. Trans- 
 
272 MANUAL OF ASSAYING. 
 
 lated by Wm. Crookes and E. Rohrig. Vol. i, 
 
 Lead, Silver, Zinc, etc., 1868; Vol. 2, Copper and 
 
 Iron, 1869; Vol. 3, Steel, Fuel and Supplement,. 
 
 1870. London. 
 Lock, A. G.: Gold; Its Occurrence and Extraction. 
 
 London and New York, 1882. 
 Percy, John : Metallurgy. The Art of Extracting Met- 
 als from their Ores. Part I, Silver and Gold. 
 
 London, i88o. 
 Percy, John : The Metallurgy of Lead. London, 1870. 
 Percy, John : The Metallurgy of Fuel, Wood, Peat, 
 
 Coal, Charcoal, Fire-clays. Revised edition. 
 Callon, J.: Lectures on Mining. 3 vols. London and 
 
 Paris, 1876-81. 
 Lamborn, P. If.: Metallurgy of Copper. 6th edition. 
 
 London, 1875. 
 Lamborn, R. H.: Metallurgy of Silver and Lead. 6th 
 
 edition. London, 1878. 
 Kustel, G.: Roasting of Gold and Silver Ores, and the 
 
 Extraction of their Respective Metals without 
 
 Quicksilver. New edition (2d). San Francisco, 
 
 1880. 
 Makin, G. H.: A Manual of Metallurgy. 2d edition. 
 
 London, 1873. 
 Collins, J. H.. A Frst book of Mining and Quarrying. 
 
 London, 1872. 
 
APPENDIX. 2 73 
 
 Assaying. 
 
 Balling, C. A. M.: Die Probirkunde des Eiseris und der 
 Brennmaterialen. Prag, 1868. 
 
 Balling, C. A. M.: Die Probirkunde. Anleitung zur 
 Vornahme docimastischer untersuchungen der 
 Berg-und Hiitten producte. Braunschweig, 1879. 
 
 Bodeman, Tk., and Bruno Kerl: Anleitung zur Berg- 
 und Hiittenmannischen Probirkunde. 2d edition. 
 Clausthal, 1857. 
 
 Bodemann, Th., and Bruno Kerl : A Treatise on the 
 Assaying of Lead, Copper, Silver, Gold and Mer- 
 cury. Translated by W. A. Goodyear. New 
 York, 1865. 
 
 Kerl, Bruno: Metallurgische Probirkunst. 2d edition. 
 Leipsig, 1882. 
 
 Lieber, O. M.. The Assayer's Guide. Phila., 1852. 
 
 Mitchell, John: A Manual of -Practical Assaying. 
 Edited by Wm. Crooks. 5th edition. New York, 
 1881. 
 
 North, Oliver: The Practical Assayer. London, 1874. 
 
 Overman, F.: Practical Mineralogy, Assaying and 
 Mining. Phila., 185 1. 
 
 Phillips, J. S.: The Explorers' and Assayers' Com- 
 panion. San Francisco, 1879. 
 
 Ricketts, P. de P.: Notes on Assaying and Assaying 
 
 Schemes. New York, 1879. 
 18 
 
2 74 MANUAL OF ASSAYING. 
 
 Silversmith, /.: A Practical Hand-book for Miners, 
 
 Metallurgists and Assayers. New York, 1866. 
 Triplett, Frank : How to Assay. St. Louis, i88i.* 
 
 Metric System; Weights and Measures. 
 Barnard, F. A. P.: The Metric System of Weights 
 
 and Measures. 2d edition. New York, 1872. 
 Eggleston, T.: Tables of Weights, Measures, Coins, 
 
 etc. New York, 1871. 
 
 Mining Law. . 
 Copp, H. N.: American Mining Code. 3d edition. 
 
 1880. 
 Carpenter, M. £.: Mining Code. 3d edition. 1880. 
 Wade, W. P.: Manual of Mining Law. St. Louis. 
 
 1882. 
 Wilson, C. S.: Mining Laws of the United States, 
 
 Colorado, New Mexico and Arizona. 1881. 
 
 It is not pretended that the above list is complete, 
 nor even that it comprises all the best works; it is 
 simply a list of some that are considered standard 
 authorities in their respective lines, save perhaps in 
 the department of assaying, where certain ones are 
 included that are not particularly valuable. 
 
 * Besides the above, there have been a number of publications from 1741 to 
 about 1850 which are either obsolete in their teachings, or the information con- 
 tained therein is embraced in the preceding. 
 
APPENDIX. 
 
 275 
 
 FORM FOR CERTIFICATE OF ASSAY. 
 
 Almost every assayer has his own particular blank, 
 but SO long as the certificate states plainly the results 
 of his work, any little differences of detail are un- 
 important. The form given below is about as satis- 
 factory as any. 
 
 01 
 
 ^ ■ 
 
 1^ 
 
 
 f 
 
 I HEREBY CERTIFY that the Samples of Ores herein described, 
 and assayed for gave the following results: 
 
 > 
 
 
 
 . "^ 
 3 
 
 
 n 
 
 X 
 
 H 
 
 » 
 
 
 a 
 
 •a 
 cr. 
 
 g 
 
 
 Gold, 
 
 No. of 
 
 ounces 
 
 per 
 
 ton. 
 
 
 Value 
 
 per 
 oz. 
 
 
 Silver, 
 
 No. of 
 
 ounces 
 
 per 
 
 ton. 
 
 
 Value 
 at 
 
 per. 
 oz. 
 
 
 Total 
 Value 
 per ton 
 
 of 
 
 Gold 
 
 and 
 
 Silver. 
 
 
 Cop- 
 per, 
 per 
 cent. 
 
 
 
 
 1 
 
 en 
 
276 MANUAL OF ASSAYING. 
 
 OUTFIT. 
 
 With the following outfit, it is believed the 
 assayer can perform the ordinary crucible and 
 scorification assays of gold, silver, copper and 
 lead ores : 
 
 Hammers, sledge, medium and small $2 00 
 
 Iron mortar (8 inch diam., i gal. capacity) and 
 
 pestle, wt. 19 lbs i 25 
 
 Steel spatulas, one large and one small 75 
 
 Sieves, 20, 40 and-ioo mesh 2 50 
 
 Hand-scales for fluxes ...."; 3 00 
 
 Ore or pulp scales 22 00 
 
 Assay balance, with weights ( i grm down to 
 
 •jij mgrm) 65 °° 
 
 Set gramme weights, 100 grms down 6 00 
 
 Set assay ton weights 6 50 
 
 Furnace, Brown's portable 20 00 
 
 6 Muffles, Battersea J 8 25 
 
 I pair crucible tongs i 25 
 
 I pair scorifier tongs i 00 
 
 I pair cupel tongs i 00 
 
 Shovel, scraper and hoe 75 
 
 Scorification mould i 00 
 
 Crucibles, S. T. U. V., i doz each, with covers 4 50 
 
 Crucibles, Colorado, 2 doz i 10 
 
APPENDIX. 277 
 
 Scorifiers, 200 2% inch, 20b 2\ inch 9 5° 
 
 Cupels, 4 doz. I inch 3 00 
 
 Cupel mould 2 25 
 
 Piece rubber cloth i 00 
 
 Alcohol lamp 50 
 
 Ring stand i 00 
 
 Wire triangle 10 
 
 I doz. 1 inch porcelain capsules 2 00 
 
 I doz. ij inch porxrelam caffeoles 2 50 
 
 I quart wash-bottle 75 
 
 1 pair 3 inch watch-glassy 50 
 
 Blow-pipe 20 
 
 Magnifying glass, pocket size 75 
 
 Magnet 20 
 
 Small steel hammer and anvil i 75 
 
 Pair brass pincers 25 
 
 Small cold chisel 50 
 
 Horn spoon 25 
 
 1 lb. bottle pure nitric acid 50 
 
 2 lbs. bi-carbonate soda 20 
 
 1 lb. carbonate of potash 20 
 
 \ lb. cyanide of potash 25 
 
 \ lb. borax glass 50 
 
 2 lbs. flour 20 
 
 1 lb. argol 18 
 
 2 lbs. nitre (nitrate potash) 30 
 
 2 lbs. litharge 21; 
 
278 MANUAL OF ASSAYING. 
 
 I lb. charcoal, pulverized 25 
 
 I lb. silica 20 
 
 \ lb. sheet lead 25 
 
 1 lb. granulated lead 40 
 
 2 lbs. bone-ash 36 
 
 ■J- oz. pure silver foil 75 
 
 $179 64 
 Note-books, gummed labels, tin boxes for dry re- 
 agents, bottles, bags or boxes for samples, etc., accord- 
 ing to fancy of purchaser. 
 
SECTION III. 
 
 TABLES. 
 
 MULTIPLICATION TABLE FOR GOLD AND SILVER, 
 
 SILVER. 
 
 GOLD. 
 
 OUNCES. 
 
 VALUE. 
 
 OUNCF.S 
 
 VALUE. 
 
 I 
 
 2 
 
 3 
 
 4 
 
 5 
 
 6 
 
 7 
 
 8 
 
 9 
 
 $1 29 
 
 2 58 
 
 3 87 
 
 5 16 
 
 6 45 
 
 7 74 
 9 °3 
 
 10 32 
 
 11 61 
 
 I 
 
 2 
 
 3 
 
 4 
 
 5 
 
 6 
 
 7 
 
 8 
 
 9 • 
 
 $20 67 
 
 41 34 
 62 01 
 82 68 
 
 103 35 
 
 124 02 
 
 144 69 
 
 165 36 
 186 03 
 
 Note. — ^The above table is more relative than actual. $20.00 is commonly 
 used as a factor for gold, and for silver the value per ounce fluctuates with 
 the market. 
 
 279 
 
28o 
 
 MANUAL OF ASSA YING. 
 
 TABLE OF VALUES OF GOLD AND SILVER. 
 
 Of Gold is 
 worth 
 
 Of Silver is 
 worth 
 
 I grain Troy 
 
 I pennyweight Troy =24 
 grains Troy 
 
 I ounce Troy =20 penny- 
 weights Troy=48o grains 
 Troy 
 
 I ounce Avoirdupois = 437^ 
 grains Troy 
 
 I pound Troy= 12 ounces Troy 
 = 240 pennyweights Troy= 
 5,760 grains Troy 
 
 I pound Avoirdupois = 16 
 ounces Avoirdupois = 7,000 
 grains Troy 
 
 I ton Avoir. = 2,000 pounds 
 
 Avoir i 29i^^^ ounces Troy ) 
 
 nvuil . -J :j2,ooo ounces Avoir. ( 
 
 14,000,000 grains Troy 
 
 $0.0430 
 i-°335 
 
 20.6718 
 18.8415 
 
 248.0620 
 
 301.4642 
 
 602,928.4660 
 
 $0.0026 
 0.0646 
 
 1.2929 
 1.1784 
 
 18.8551 
 37,710.3846 
 
 Note. — The above values are figured on the basis of $20.67 per 
 Troy oz. for gold, and $1.29 for silver. Were the factors made $20 
 for gold, and the fluctuation prices of $1.10 and $1.15 for silver, the 
 values given would be varied considerably. . 
 
APPENDIX. 281 
 
 TABLES OF WEIGHTS. 
 
 AVOIRDUPOIS WEIGHT. 
 
 16 Drams=i Ounce. 
 16 Ounces = i Pound. 
 28 Pounds= I Quarter.* 
 , 4 Quarters= i Hundred weight. 
 20 Hundred weight =1 Ton of 2240 pounds. 
 
 AVOIRDUPOIS WEIGHT. 
 
 I dram. 
 
 I ounce=i6 drams. 
 
 I pounds 16 ounces=256 drams. 
 
 I quarter=28 pounds=448 ounces=7i68 drams. 
 
 I h'dwt=4quarters=ii2 pounds=:i792 ounces^28672 
 
 drams. 
 I ton=2o h'dwt=8o quarters = 2240 pounds = 35840 
 
 ounces=57344o drams. 
 
 AVOIRDUPOIS WEIGHT. 
 
 25 Pounds=i Quarter. 
 4 Quarters= i Hundred weight. 
 20 Hundred weights i Ton of 2000 pounds. 
 
 AVOIRDUPOIS WEIGHT. 
 
 I quarter=25 pounds=4oo ounces=64oo drams. 
 
 * In some parts of the United States. 
 
282 MANUAL OF ASSAYING. 
 
 I h'dwt=4 quarters =100 pounds =1600 ounces = 
 
 25600 drams. 
 I ton = 2o hdwt=8o quarters=2ooo pounds = 32000 
 
 ounces=5i2ooo drams. 
 
 TROY WEIGHT. 
 
 24 Grains=i Pennyweight. 
 20 Pennyweights := i Ounce. 
 12 Ounces=i Pound. 
 
 TROY WEIGHT. 
 
 I grain. 
 
 I pennyweight= 24 grains. 
 
 I ounce=2o pennyweights=48o grains. 
 
 I pound = i2 ounces=24o pennyweights=576o grains. 
 
 apothecaries' weight. 
 
 20 Grains=i Scruple. 
 
 3 Scruples=i Dram. 
 
 8 Drams=i Ounce. 
 12 Ounces=i Pound. 
 
 apothecaries' weight. 
 I grain. 
 
 I scruple=20 grains. 
 I dram =3 scruples =60 grains. 
 I ounce=:8 drams=:24 scruples=48o grains. 
 I pound=i2 ounces=96 drams=288 scruples=S76o 
 grains. 
 
APPENDIX. 
 
 283 
 
 I pound, Troy, 
 
 I pound. Apothecaries', 
 
 I pound, Avoirdupois, 
 
 =5760 grains. 
 = 5760 grains. 
 = 7000 Troy grains. 
 
 FRENCH OR METRIC SYSTEM OF WEIGHTS. 
 
 1 Milligramme =.001 of a Gramme. 
 
 I Centigramme =.oi " " 
 
 I Decigramme =.i " " 
 
 I Gramme = i Gramme. 
 
 I Decagramme = lo Grammes. 
 I Hectogramme = 100 " 
 
 I Kilogramme = 1000 " 
 
 I Myriagramme = loooo " 
 
 or 
 10 Milligrammes (mgrs) = I Centigramme (cgr). 
 
 10 Centigrammes 
 10 Decigrammes 
 10 Grammes 
 10 Decagrammes 
 10 Hectogrammes 
 10 Kilogrammes 
 
 = 1 Decigramme (dgr). 
 = 1 Gramme (grm). 
 = I Decagramme (dkgr). 
 =:i Hectogramme (hgr). 
 = 1 Kilogramme (kgr). 
 = 1 Myriagramme(myrgr). 
 
 I mgr. 
 
 I cgr. = 10 mgrs. 
 I dgr. = 10 cgrs. = ioo mgrs. 
 I grm. = io dgrs.= ioo cgrs.= 1,000 mgrs. 
 I dkgr.= io grms.= 100 dgrs.= 1,000 cgrs.= 10,000 
 mgrs. 
 
284 MANUAL OF ASSA YING. 
 
 I hgr.= 10 dkgrs.= 100 grms.= 1,000 dgrs.= 10,000 
 
 cgrs. = 100,000 mgrs. 
 I kgr.=: 10 hgrs.= 100 dkgrs.= 1,000 grms.= 10,000 
 
 dgrs. = 100,000 cgrs. = 1,000,000 mgrs. 
 I myrgr.= io kgrs. = ioo hgrs. = 1,000 dkgrs.= 10,000 
 
 grms.= 100,000 dgrs. = 1,000,000 cgrs. = 10,000,000 
 
 mgrs. 
 
 I gramme= 15.43235 Troy grains. 
 
APPENDIX. 
 
 285 
 
 EQUIVALENTS OF SOME OF 
 
 ' THE ENGLISH AND FRENCH 
 
 WEIGHTS.* 
 
 
 Troy Grains. 
 
 
 Grammes. 
 
 I 
 
 = 
 
 .064798 
 
 2 
 
 = 
 
 .129597 
 
 3 
 
 = 
 
 .194396 
 
 4 
 
 = 
 
 •259195 
 
 5 
 
 =: 
 
 ■323994 
 
 6 
 
 = 
 
 388793 
 
 7 
 
 = 
 
 •453592 
 
 8 
 
 = 
 
 ■518391 
 
 9 
 
 = 
 
 .583190 
 
 Grammes. 
 
 
 Troy Grains. 
 
 I 
 
 = 
 
 15-43235 
 
 2 
 
 — 
 
 30.86470 
 
 3 
 
 = 
 
 46.29705 
 
 4 
 
 = 
 
 61.72940 
 
 5 
 
 = 
 
 77.16175 
 
 6 
 
 = 
 
 92.59410 
 
 7 
 
 = 
 
 108.02645 
 
 8 
 
 = 
 
 123.45880 
 
 9 
 
 r= 
 
 138.89115 
 
 *T. Eggleston's Tables of Weights, Measures, Coins, etc., 
 p. 24. 
 
286 
 
 MANUAL OF ASSAYING. 
 
 ASSAY TON EQUIVALENTS IN GRAMMES, TROY 
 
 GRAINS, AND TROY OUNCES. 
 
 Based on i gramme=i5. 43235 Troy grains; hence 1 assay ton 
 or 2g.i66 grammes=i5.43235 x 29.166=450.09992 Troy grains. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 0.05 
 
 1.458 
 
 22.504 
 
 
 0.10 
 
 2.916 
 
 45.009 
 
 
 0.15 
 
 4.374 
 
 67.514 
 
 
 0.20 
 
 5.833 
 
 90.019 
 
 
 0.25 
 
 7.291 
 
 112.524 
 
 
 0.30 
 
 8.749 
 
 135.029 
 
 
 0.35 
 
 10.208 
 
 157.534 
 
 
 0.40 
 
 11.666 
 
 180.039 
 
 
 0.45 
 
 13.124 
 
 202.544 
 
 
 0.50 
 
 14.583 
 
 225.049 
 
 
 0.55 
 
 16.041 
 
 247.554 
 
 
 0.60 
 
 17.499 
 
 270.059 
 
 
 0.65 
 
 18.958 
 
 292.564 
 
 
 0.70 
 
 20.416 
 
 315.069 
 
 
 0.75 
 
 21.874 
 
 337 . 574 
 
 
 0.80 
 
 23.333 
 
 360.079 
 
 
 0.85 
 
 24.791 
 
 382.584 
 
 
 0.90 
 
 26.249 
 
 405.089 
 
 
 0.95 
 
 27.708 
 
 427.594 
 
 
 1.00 
 
 29.166 
 
 450.099 
 
 
APPENDIX. ■■ 
 
 287 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 1.05 
 
 30.624 
 
 472.604 
 
 
 1.10 
 
 32.083 
 
 495.109 
 
 1.032 
 
 1.15 
 
 33.541 
 
 517.614 
 
 1.078 
 
 1.20 
 
 34.999 
 
 540.119 
 
 1.125 
 
 1.25 
 
 36.458 
 
 562.624 
 
 1.173 
 
 1.30 
 
 37.916 
 
 585.129 
 
 1.219 
 
 1.35 
 
 39.374 
 
 607.634 
 
 1.266 
 
 1.40 
 
 40.833 
 
 630.139 
 
 1.313 
 
 1.45 
 
 42.291 
 
 652.644 
 
 1.360 
 
 1.50 
 
 43.749 
 
 675.149 
 
 1.407 
 
 1.55 
 
 45.208 
 
 697.654 
 
 1.453 
 
 1.60 
 
 46.666 
 
 720.159 
 
 1.500 
 
 1.65 
 
 48.124 
 
 742.664 
 
 1.547 
 
 1.70 
 
 49.583 
 
 765.169 
 
 1.594 
 
 1.75 
 
 51.041 
 
 •787.674 
 
 1.641 
 
 1.80 
 
 52.499 
 
 810.179 
 
 1.667 
 
 1.85 
 
 53.958 
 
 832.684 
 
 1.735 
 
 1.90 
 
 55.416 
 
 855.189 
 
 1.782 
 
 1.96 
 
 56.874 
 
 877.694 
 
 1.829 
 
 2.00 
 
 58.333 
 
 900.199 
 
 1.875 
 
288 
 
 MANUAL OF ASSAYING. 
 
 ASSAY 
 
 TON EQUIVALENTS CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 2.05 
 
 59.791 
 
 922.704 
 
 1.922 
 
 2.10 
 
 61.249 
 
 945 . 209 
 
 1.969 
 
 2.15 
 
 62.708 
 
 967.714 
 
 2.016 
 
 2.20 
 
 64.166 
 
 990.219 
 
 2.063 
 
 2.25 
 
 65.624 
 
 1012.724 
 
 2.110 
 
 2.30 
 
 67.083 
 
 1035.229 
 
 2.157 
 
 2.35 
 
 68.541 
 
 1057.734 
 
 2.204 
 
 2.40 
 
 69.999 
 
 1080.239- 
 
 2.250 
 
 2.45 
 
 71.458 
 
 1102.744 
 
 2.297 
 
 2.50 
 
 72.916 
 
 1125.249 
 
 2.344 
 
 2.55 
 
 74.374 
 
 1147.754 
 
 2.391 
 
 2.60 
 
 75.833 
 
 1170.259 
 
 2.438 
 
 2.65 
 
 77.291 
 
 1192.764 
 
 2.485 
 
 2.70 
 
 78 . 749 
 
 1215.269 
 
 2.531 
 
 2.75 
 
 80.208 
 
 1237.774 
 
 2 . 579 
 
 2.80 
 
 81.666 
 
 1260.279 
 
 2.626 
 
 2.85 
 
 83.124 
 
 1282.784 
 
 2.672 
 
 2.90 
 
 84.583 
 
 1305.289 
 
 2.719 
 
 2.95 
 
 86.041 
 
 1327.794 
 
 2.766 
 
 3.00 
 
 87.499 
 
 1350.299 
 
 2.813 
 
APPENDIX. 
 
 289 
 
 ASSAY TON EQUIVALENTS — CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 3.05 
 
 88.958 
 
 1372.804 
 
 2.860 
 
 3.10 
 
 90.416 
 
 1395.309 
 
 2.905 
 
 3.15 
 
 91 . 874 
 
 1417.814 
 
 2.954 
 
 3.20 
 
 93.333 
 
 1440.319 
 
 3.001 
 
 3.25 
 
 94.791 
 
 1462.824 
 
 3.048 
 
 3.30 
 
 96 . 249 
 
 1485.329 
 
 3.094 
 
 3.35 
 
 97 . 708 
 
 1507.834 
 
 3.141 
 
 3.40 
 
 99.166 
 
 1530.339 
 
 3 . 188 
 
 3.45 
 
 100.624 
 
 1552.844 
 
 3.235 
 
 3.50 
 
 102.083 
 
 1575 . 349 
 
 3.282 
 
 3.55 
 
 103 . 541 
 
 1597.854 
 
 ■ 3.329 
 
 3.60 
 
 104. 999 
 
 1620.359 
 
 3.376 
 
 3.65 
 
 106.458 
 
 1642.864 
 
 3.423 
 
 3.70 
 
 107.916 
 
 1665.369 
 
 3.470 
 
 3.75 
 
 109.374 
 
 1687.874 
 
 3.516 
 
 3.80 
 
 110.833 
 
 1710.379 
 
 3.563 
 
 3.85 
 
 112.291 
 
 1732.884 
 
 3.610 
 
 3.90 
 
 118.749 
 
 1755.389 
 
 3.657 
 
 3.95 
 
 115.208 
 
 1777.894 
 
 3.704 
 
 4.00 
 
 116.666 
 
 1800.399 
 
 3.751 
 
 19 
 
290 
 
 MANUAL OF ASSAYING. 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 4 05 
 
 118.124 
 
 1822.904 
 
 3.798 
 
 4.10 
 
 119.583 
 
 1845.409 
 
 3.845 
 
 4.15 
 
 121.041 
 
 1867.914 
 
 3.891 
 
 4.20 
 
 122.499 
 
 1890.419 
 
 3.938 
 
 4.25 
 
 128.958 
 
 1912.924 
 
 3.985 
 
 4.30 
 
 125.416 
 
 1935.429 
 
 4.032 
 
 4.35 
 
 126.874 
 
 1957.934 
 
 4.079 
 
 4.40 
 
 128.333 
 
 1980.439 
 
 4.126 
 
 4.45 
 
 129.791 
 
 2002 . 944 
 
 4.173 
 
 4.50 
 
 131.249 
 
 2025 . 449 
 
 4.220 
 
 4.55 ■ 
 
 132.708 
 
 2047.954 
 
 4.267 
 
 4.60 
 
 134.166 
 
 2070.459 
 
 4.313 
 
 4.65 
 
 135.624 
 
 2092 . 964 
 
 4.360 
 
 4.70 
 
 137.083 
 
 2115.469 
 
 4.407 
 
 4.75 
 
 138.541 
 
 2137.974 
 
 4.454 
 
 4.80 
 
 139.999 
 
 2160.479 ' 
 
 4.500 
 
 4.85 
 
 141.458 
 
 2182.984 
 
 4.548 
 
 4.90 
 
 142.916 
 
 2205.489 
 
 4.595 
 
 4.95 
 
 144.374 
 
 2227 . 994 
 
 4.642 
 
 5.00 
 
 145 . 833 
 
 2250.499 
 
 4.689 
 
APP-ENDIX. 
 
 291 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay- 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 5.05 
 
 147.291 
 
 2273.004 
 
 4.735 
 
 5.10 
 
 148 . 749 
 
 2295.509 
 
 4.782 
 
 5.15 
 
 150.208 
 
 2318.014 
 
 4.829 
 
 5.20 
 
 151.666 
 
 2340.519 
 
 4.876 
 
 5.25 
 
 153 . 124 
 
 23ii3.024 
 
 4.923 
 
 5.30 
 
 154.583 
 
 2885 . 529 
 
 4.970 
 
 5.35 
 
 156.041 
 
 2408 . 034 
 
 5.017 
 
 5.40 
 
 157.499 
 
 2430.589 
 
 5.0G4 
 
 5.45 
 
 158.958 
 
 2458 . 044 
 
 5.111 
 
 5.50 
 
 160.416 
 
 2475.549 
 
 5.157 
 
 5.65 
 
 161.874 
 
 2498 . 054 
 
 5.204 
 
 5.60 
 
 163.383 
 
 • 2520.559 
 
 5,251 
 
 5.65 
 
 164.791 
 
 2548 . 064 
 
 5.298 
 
 5.70 
 
 166.249 
 
 2565.569 
 
 5.345 
 
 5.75 
 
 167.708 
 
 2588.074 
 
 5 . 892 
 
 .5.80 
 
 169.166 
 
 2610.579 
 
 5.439 
 
 5.85 ' 
 
 170.624 
 
 2633.084 
 
 5.486 
 
 5.90 
 
 172.083 
 
 2655.589 
 
 5.532 
 
 5.95 
 
 173.541 
 
 2678.094 
 
 5.579 
 
 6.00 
 
 174.999 
 
 2700.579 
 
 5.626 
 
292 
 
 MANUAL OF ASSAYING. 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value, in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 TroyOunces. 
 
 6.05 
 
 176.458 
 
 2723.084 
 
 5 . 673 
 
 6.10 
 
 177.916 
 
 2745.589 
 
 5.720 
 
 6.15 
 
 179.374 
 
 2768.094 
 
 . 767 
 
 6.20 
 
 180.833 
 
 2790.599 
 
 5.814 
 
 6.25 
 
 182.291 
 
 2813.104 
 
 5.861 
 
 6.30 
 
 183.749 
 
 2835.609 
 
 5.908 
 
 6.35 
 
 185.208 
 
 2858.114 
 
 5.954 
 
 6.40 
 
 186.666 
 
 2880.619 
 
 6.001 
 
 6.45 
 
 188.124 
 
 2903.124 
 
 6.048 
 
 6.50 
 
 189 . 583 
 
 2925.629 
 
 6.095 
 
 6.55 
 
 191.041 
 
 2948.134 
 
 6.142 
 
 6.60 
 
 192.499 
 
 2970.639 
 
 6.189 
 
 6.65 
 
 l!i3.958 
 
 2993.144 
 
 6.236 
 
 6.70 
 
 195.416 
 
 3015.649 
 
 6.283 
 
 6.75 
 
 196.874 
 
 3038.154 
 
 6.329 
 
 6.80 
 
 198.333 
 
 3060.659 
 
 6.376 
 
 6.85 
 
 199.791 
 
 3083.164 
 
 6.423 
 
 6.90 
 
 201.249 
 
 3105.669 
 
 6.470 
 
 6.95 
 
 202.708 
 
 3128.174 
 
 6.517 
 
 7.00 
 
 204.166 
 
 3150.679 
 
 6.564 
 
APPENDIX. 
 
 293 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay- 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 7.05 
 
 205.624 
 
 3173.184 
 
 6.611 
 
 7.10 
 
 207.083 
 
 3195.689 
 
 6.658 
 
 7.15 
 
 208 . 541 
 
 3218.194 
 
 6.705 
 
 7.20 
 
 209.999 
 
 3240.699 
 
 6.751 
 
 7.25 
 
 211.458 
 
 3263.204 
 
 6.798 
 
 7.30 
 
 212.916 
 
 3285.709 
 
 6.845 
 
 7.35 
 
 214.374 
 
 3308.214 
 
 6.892 
 
 7.40 
 
 215.833 
 
 3330.719 
 
 6.939 
 
 7.45 
 
 217.291 
 
 3353 . 224 
 
 6.986 
 
 7.50 
 
 218.749 
 
 3375.729 
 
 7.033 
 
 7.55 
 
 220.208 
 
 3398.234 
 
 7.080 
 
 7.60 
 
 221.666 
 
 3420.739 
 
 7.127 
 
 7.65 
 
 223.124 
 
 3443 . 244 
 
 7.173 
 
 7.70 
 
 224.583 
 
 3465.749 
 
 7.220 
 
 7.75 
 
 226.041 
 
 3488.254 
 
 7.267 
 
 7.80 
 
 227.499 
 
 3510.759 
 
 7.314 
 
 7.85 
 
 228.958 
 
 3533 . 264 
 
 7.361 
 
 7.90 
 
 230.416 
 
 3555.769 
 
 7.408 
 
 7.95 
 
 231.874 
 
 35-78 . 274 
 
 7.455 
 
 8.00 
 
 233.333 
 
 3600.779 
 
 7.502 
 
294 
 
 MANUAL OF ASSA YING. 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 TroyOunces. 
 
 8.05 
 
 234.791 
 
 3623 . 284 
 
 7 . 540 
 
 8.10 
 
 236.249 
 
 3645.789 
 
 7 . 595 
 
 8.15 
 
 237.708 
 
 3668.294 
 
 7.642 
 
 8.20 
 
 239.166 
 
 3690.799 
 
 7.689 
 
 8.25 
 
 240 . 624 
 
 3713.304 
 
 7.736 
 
 8.30 
 
 242.083 
 
 3735.809 
 
 7.783 
 
 8.35 
 
 243 . 541 
 
 3758.314 
 
 7.830 
 
 8.40 
 
 244.999 . 
 
 3780.819 
 
 7.877 
 
 8.45 
 
 246.458 
 
 3803 . 324 
 
 7.924 
 
 8.50 
 
 247.916 
 
 3825.829 
 
 7 . 970 
 
 8.55 
 
 249.374 
 
 3848.334 
 
 8.017 
 
 8.60 
 
 250.833 
 
 3870 . 839 
 
 8.064 
 
 8.65 
 
 252.291 
 
 3893 . 344 
 
 8.111 
 
 8.70 
 
 253 . 749 
 
 3915.849 
 
 8.158 
 
 8.75 
 
 255 . 208 
 
 3938.354 
 
 8.205 
 
 8.80 
 
 256.666 
 
 3960.859 
 
 8.252 
 
 8.85 
 
 258.124 
 
 3983 . 364 
 
 8.299 
 
 8.90 
 
 259.583 
 
 4005 . 869 
 
 8.346 
 
 8.95 
 
 261.041 
 
 4028.374 
 
 8.392 
 
 9.00 
 
 262.449 
 
 4050.879 
 
 8.439 
 
APPENDIX. 
 
 295 
 
 ASSAY TON EQUIVALENTS CONTINUED. 
 
 Assay 
 
 Value in 
 
 Value in 
 
 Value in 
 
 Tons. 
 
 Grammes. 
 
 Troy Grains. 
 
 Troy Ounces. 
 
 9.05 
 
 263.958 
 
 • 4073.384 
 
 8.486 
 
 9.10 
 
 265.416 
 
 4095.889 
 
 8 . 533 
 
 9. 15 
 
 266.874 
 
 4118.394 
 
 8.580 
 
 9.20 
 
 268.333 
 
 4140.899 
 
 8.627 
 
 9.25 
 
 269.791 
 
 4163.404 
 
 8.674 
 
 9.30 
 
 2.71 . 249 
 
 4185.909 
 
 8.721 
 
 B.35 
 
 272 . 708 
 
 4208.414 
 
 - 8.768 
 
 9.40 
 
 274.166 
 
 4230.919 
 
 8.814 
 
 9.45 
 
 275.624 
 
 4253 . 424 
 
 8.861 
 
 9.50 
 
 i}77.083 
 
 4275 . 929 
 
 8.908 
 
 9.55 
 
 278.541 
 
 4298 . 434 
 
 8.955 
 
 9.60 
 
 279.999 
 
 4320 . 939 
 
 9.002 
 
 9.65 
 
 281.458 
 
 4343 . 444 
 
 9.049 
 
 9.70 
 
 282.916 
 
 4365.949 
 
 9.096 
 
 9.75 
 
 284.374 
 
 4388 . 454 
 
 9,143 
 
 9.80 
 
 285.833 
 
 4410.959 
 
 9.189 
 
 9.85 
 
 287.291 
 
 4433 . 464 
 
 9.236 
 
 9.90 
 
 288.749 
 
 4455 . 969 
 
 9.283 
 
 9.95 
 
 290.208 
 
 4478 . 474 
 
 9.330 
 
 10.00 
 
 291.666 
 
 4500 . 979 
 
 9 . 377- 
 
IN^DEX. 
 
 A. 
 
 Acetate of lead, re-agent, 105. 
 
 AcicuLAR BISMUTH, mineral, 262. 
 
 Acid flux, silica, 101. 
 
 Acid, htdeochloric (muriatic), 
 109. 
 
 Acid, NTTBic; re-agent, 107, 110; 
 preparationof various strengths, 
 1G3; to free from chlorine, 107. 
 
 Acid, sulphuric, re-agent, 113. 
 
 AiKiNiTE, mineral, 258, 262. 
 
 Alaskaite, mineral, 258, 265. 
 
 Alcohol, re-agent, 108. 
 
 Alden crusher, 19. 
 
 Algodoxite, mineral, 261, 262. 
 
 Alphabets and. figures, steel, 90. 
 
 Altaite, mineral, 258, 261, 265. 
 
 Alumina and lead phosphate, 
 267. 
 
 Aluminium, element, 11. 
 
 Amalgamation, assay, 221; mor- 
 tar, 91. 223. 
 
 Amalgam, gold, mineral, 257. 
 
 Ammonia, aqua (caustic, hydrate, 
 waters 108; carbonate, 94, 99; 
 citrate, 109. 
 
 Analysis, books on, 269, 270; cop- 
 per ores, 210; definition, 13; re- 
 agents for, 108. 
 
 Anglesite, mineral, 265. 
 
 Annealing cups, 76, 242; plate, 
 76, 241. 
 
 Antimonial red silver ore, 200 ; sil- 
 ver, 130, 259; sulphide of silver 
 and lead, 259, 266. 
 
 Antimony, and lead sulphide, 265 ; 
 and silver sulphide, 130, 259, 
 260 ; arsenic and silver sulphide, 
 130, 259 ; bismuth and lead sul- 
 phide, 266 ; copper and lead sul- 
 phide, 262, 265 ; cupel color, 
 247; element, 11; native, 261; 
 oxide, 260; vapors, 246. 
 
 Anvils, and method of mounting, 
 85. 
 
 Apothecaries' weights,- tables of, 
 282. 
 
 Apparatus, for analysis and assay- 
 ing, 17 ; glass and porcelain, 
 77; miscellaneous, 81; sulphu- 
 retted hydrogen, 113; used in 
 furnace, 68. 
 
 Argentiferous gold, 257, 259; 
 gray copper, 131; lead ores, 
 131; ores, 131; pyrites, 132; 
 zinc blende, 132. 
 
 Argentic nitrate, re-agent, 110. 
 
 Argentite, mineral, 258. 
 
 Argol, re-agent, 93, 98; reducing 
 power, 121. 
 
 897 
 
298 
 
 INDEX. 
 
 "Arrastre," 91, 233. 
 
 Arsenate, lead, mineral, 266. 
 
 Arsenic, antimony and silver 
 sulphide, 130, 259; cupel color, 
 247; element, 11; native, 258, 
 261; vapors, 246. 
 
 Arsenical, copper, 263; silver 
 ore, 130, 259. 
 
 Arsenide, copper, mineral, 263, 
 263, 265. 
 
 Arsenopyrite, mineral, 129, 258, 
 261. 
 
 Assay, amalgamation, 221; base 
 bullion, 243; certificate, 275; 
 chlorination, 234; copper, 181; 
 galena, 186; gold and silver, 
 133; gold bullion, 239; lead, 
 186; ton equivalents, 286; ton 
 weights, 40; ton weights, ex- 
 planation, 41. 
 
 Assaying, apparatus, 17; books 
 on, 273; definition, 13; dry re- 
 agents for, 93; free gold and 
 silver ores, 203; of various 
 minerals in an ore, 201 ; outfit, 
 276; re-agents used in, 93; wet 
 re-agents used in, 106. 
 
 Atacamite, mineral, 262. 
 
 Attwood, blow pipe assaying, 
 271 ; reference to, 237. 
 
 AuRicHALOiTB, mineral, 262. 
 
 ACRIFEROUS SULPHURETS, 129. 
 
 Austin, L. S., references to, 134, 
 
 245. 
 Average samples, obtaining of, 
 
 134. 
 
 Avoirdupois weights, tables of, 
 
 281. 
 Azure copper ore (azurite), 
 
 181, 263. 
 
 B 
 
 Balances, Becker's, 29, 33-4-5; 
 bullion, 33; for weighing gold 
 and silver beads, 3i; Oertling's, 
 35; Troemner's, 39, 30, 33-4r-5. 
 
 Balling's Works on Assaying, 
 273. 
 
 Barium, chloride (muriate), re- 
 agent, 109; element, 11. 
 
 Barker's Elementary Chemis- 
 try, 268. 
 
 Barnard's Metric System, 274. 
 
 Babnhardite, mineral, 261, 262. 
 
 Base bullion, assay, 243; sam- 
 pling, 245. 
 
 Basic flux, nitre, 99. 
 
 Batea, 237. 
 
 Baths, sand, 87. 
 
 Battbrsea, crucibles, 70; fur- 
 naces, 53; muffl.es, 68; roasting 
 dishes, 71; scoriflers, 73. 
 
 Battery, Bunsen carbon, 215; 
 "gravity," 317. 
 
 Beads, gold and silver, balance 
 for weighing, 33; inquarting, 
 164; parting, 141, 161; weigh- 
 ing, 141, 160. 
 
 Beakers, glass, 80. 
 
 BeaufaY crucibles, 69, 70. 
 
 Becker's bullion balances, 38- 
 4-5 ; pulp scales, 38. 
 
INDEX. 
 
 299 
 
 Bi-CAEBONATE OF SODA, re-agent 
 93, 94; properties, 94. 
 
 Bi-CHROMATE OF POTASH, re- 
 agent, 108. 
 
 Bismuth, acioular (cupreous), 263 ; 
 cupel color, 247; element, 11; 
 lead and antimony sulphide, 
 266; native, 258, 261; silver, 
 260, 267; silver and lead sul- 
 phide, 258, 260, 265, 267. 
 
 BiSMOTHiNiTE, mineral, 258. 
 
 Bl-TARTRATE OP POTASH, rC-agSnt, 
 
 98, 121. 
 Black flux substitute, 93, 98; 
 
 copper or oxide of copper, 180, 
 
 261; oxide of manganese, 108; 
 
 silver, 260; tellurium. 257, 267. 
 Blake crusher, 19. 
 Blende, 129; argentiferous, 132. 
 "BLicKiNa,"156. 
 
 "BLOSSOMDfQ," 157. 
 
 Blotting paper, 83. 
 
 Blow-pipe, 88; analysis, books 
 on, 271. 
 
 Blue carbonate of copper (blue 
 malachite, mountain blue), 181, 
 262. 
 
 Blue copper, mineral, 263. 
 
 Blue vitriol, mineral, 263. 
 
 BoDEMANN & Kerl's works on 
 assaying, 273; reference to, 
 184. 
 
 Boiling flasks, 79. 
 
 BoNE-ASH, 113. 
 
 Books, note, 81, 183; list of use- 
 ful, 268. 
 
 Borax glass, preparation of, 97; 
 re-agent, 93, 96. 
 
 BoRNiTE, mineral, 201, 262. 
 
 Boron, element, 11. 
 
 Bottle, wash, 7^. 
 
 Bottles, re-agent, 77: sample, 
 77, 184., 
 
 BouLANGERiTE, mineral, 261, 265. 
 
 BouRNONiTE, mineral, 2G2, 265. 
 
 Boxes, sample, 82, 184. 
 
 Brief scheme for silica, iron 
 and manganese, 254. 
 
 "Brightening," 156. 
 
 Brittle silver ore, mineral, 180, 
 260. 
 
 Brochantite, mineral, 262. 
 
 Bromic silver (bromide of silver, 
 bromyrite), 181, 258. 
 
 Bromine, element, 11. 
 
 Brown's assay furnace, 55. 
 
 Brushes, 81, 39, 83. 
 
 Brush's Mineralogy, 271. 
 
 Bucking hammer, 23. 
 
 Buffalo Dental Mfg. Co., 44, 46. 
 
 Bullion balances, 33; base, as- 
 say of, 243 ; base, sampling of, 
 245; gold, assay of, 289; Silver, 
 Report upon Wastage of, 339. 
 
 Bunsen battery, 215; burners, 87. 
 
 Cadmium, element, 11. 
 Cesium, element, 13. 
 Cairns' Quantitative Analysis, 
 269. 
 
300 
 
 INDEX. 
 
 Calaverite, mineral, 357, 261. 
 
 Calcium, chloride, 37, 113; ele- 
 ment, 11; hydroxide, 110. 
 
 Calc-spar, mineral, 178. 
 
 Caloulatioxs in scoriflcation 
 proeessri41, 166. 
 
 Caledonite, mineral, 263, 265. 
 
 CALLOJf's Lectures on Mining, 
 272. 
 
 Capsules, porcelain, 78. 
 
 Carbon, element, 11. 
 
 Carbonate of ammonia, re- 
 agent, 94, 99; of copper, blue 
 and green, mineral, 181, 262, 
 264; of lead, mineral, 132, 186, 
 265; of lead, re-agent, 105; of 
 potash, re-agent, 93, 95; of 
 zinc and copper, mineral, 262. 
 
 " Carbonate ores," 129. 
 
 Carbonates, tests for, 249. 
 
 Carpenter's Mining Code, 274. 
 
 Carrollite, mineral, 263. 
 
 Case, glass, for pulp-scale, 29. 
 
 Casserole, 81. 
 
 Caustic ammonia, 108; lunar, 
 110; potash, 108. 
 
 Cerabgyrite, mineral, 259. 
 
 Cerium, element, 12. 
 
 Certificate of Assay, Form for, 
 275. 
 
 Ceruse, re-agent, 105. 
 
 Cerussite, mineral, 132, 186, 261, 
 265. 
 
 Chalcanthite, mineral, 263. 
 
 Chalcocite, mineral, 181, 263. 
 
 Chalcopyrite, mineral, 181, 258, 
 261, 263. 
 
 Chalk, dry, 114; wash, 114. 
 
 Chamois skin, 93. 
 
 Charcoal, wood, charge for test- 
 ing, 122; properties of, 99; re- 
 agent, 94, 99; reducing power, 
 122. 
 
 Charges, crucible for galena, 179; 
 crucible for quartz, sand or 
 "dry" ores, 171; crucible, 
 large, 175; for antimonial and 
 arsenical ores, 169; for argol, 
 131; for basic ores, 178; for 
 charcoal, 132; for chlorides, 
 169; for copper mattes, 169; 
 for copper oxides and carbon- 
 ates, 183; for copper sulphides, 
 183; for cream of tartar, 121; 
 for granulated lead, 118; lead 
 carbonates, 194; for lead in ga- 
 lena, 180, 189, 190, 191, 193; for 
 lead oxides, 195; for lime or 
 baryta gangue, 169; for lith- 
 arge, 116; for native copper, 
 183; for nitre,. 132; for ordinary 
 seorifications, 168: for oxides of 
 iron, 170; for sulphurets, 169; 
 for tellurides, 169; for testing 
 ores, 134; in scoriflcation pro- 
 cess, 167; Low's, 177; prepara- 
 tion of, 141; Eioketts', 123, 
 134, 176, 184, 191 ; scoriflcation 
 for copper, 168; scoriflcation 
 for galena, 170; Stone's, 178. 
 
 "Checking," 75. 
 
 Chemical Technology, Wagner'.s, 
 368. 
 
 Chemistry, Barker's, 368; gen- 
 
INDEX. 
 
 301 
 
 eral, books on, 268; Miller's, 
 268; reference books on, 268; 
 Roscoe and Schorlemmer, 268; 
 Roscoe's Elementary, 269 ; theo- 
 retical text-books on, 268; 
 Watts' Dictionary, 268. 
 
 Chloride, and phosphate of lead, 
 267; baric, 109; calcic, 37. 113; 
 mercuric, 110; of silver, 131, 
 259; of sodium, 99; stannous, 
 111. 
 
 "Chloeide ores," 131. 
 
 Chlorination assay of gold ores, 
 234; test for silver, 237. 
 
 Chlorine, element, 11; in dis- 
 tilled water, 106; to free nitric 
 acid from, 107. 
 
 Chloro-bromide op silver, min- 
 eral, 259. 
 
 Cbrojiate op copper and lead, 
 mineral, 265, 267 
 
 Chromium, element, 11; color on 
 cupel, 248. 
 
 Chrysocolla, mineral, 263. 
 
 Citrate op ammonium, re-agent, 
 109. 
 
 Classen's Quantitative Analy- 
 sis, 269. 
 
 Classipication op silver ores, 
 130. 
 
 Clay crucibles, 70; lute, 114. 
 
 Clock-glasses, 78. 
 
 Cloth, oil and rubber, 82. 
 
 Cobalt, color on cupel, 248; ele- 
 ment, 11; nickel and copper 
 sulphide. 268. 
 
 Cofpee-mill, 98. 
 
 Cold chisel, 91. 
 
 Collins' Mining and Quarrying, 
 272. 
 
 Colorado crucibles, 71 ; minerals, 
 267. 
 
 CoLORADOiTE, mineral, 258, 261. 
 
 Color tests, cupel, 247; scorifiea- 
 tion, 246; scorifier, 247. 
 
 Golumbium, element, 12. 
 
 Common salt, re-agent, 94, 99. 
 
 Copper, analysis, methods, 210; 
 and iron sulphide, sulphuret or 
 pyrites, 129, 132, 181, 262, 263; 
 and lead chromate, 265, 267; 
 and silver sulphide or sulphu- 
 ret, 131, 260, 264; and uranium 
 phosphate, 264; and zinc car- 
 bonate, 262; argentiferous gray, 
 131; arsenical, 263; arsenide, 
 262, 263, 265 ; assay, 181 ; azure, 
 262; black oxide, 180, 264; 
 blue, 263; blue carbonate, 181, 
 262; blue malachite, 262; car- 
 bonates, 182; cobalt and nickel 
 sulphide, 263; color on cupel, 
 248; color on scorifier, 247; 
 element, 11; glance, 263; gray, 
 129, 181, 260, 264; green, 264; 
 green carbonate, 181, 264; in- 
 digo, 263; lead and antimony 
 sulphide, 262, 265; metallic, 
 110; metallurgy, 272; minerals 
 in the U. S., 262; muriate, 262; 
 native, 180, 261, 264; native, 
 assay, 182; occurrence, 180; 
 oxides, 182, 264; oxides, assay, 
 182; oxy-ehloride, 262; phos- 
 
30-- 
 
 INDEX. 
 
 phate, 204; purple, 262; pyr- 
 ites, 263; pyritous, 263; red 
 oxide, 180, 263; silicate, 263; 
 spatulas, 27; sulph-arsenite, 
 208, 204; sulphate, , 202, 203; 
 sulphides or sulphurets, ISI, 
 260, 263; sulphides, assay, 183; 
 tests for, 251; uranite, 264; 
 variegated, 262; vitreous, 263; 
 vitriol, 268; volumetric analy- 
 sis, 220. 
 
 Copperas, re-agent. 111. 
 
 Copp's Americak Mining Code, 
 874. 
 
 Cornwall's Blow-pipe Analysis, 
 271. 
 
 Corrosive sublimate, re-agent, 
 110. 
 
 Cotta's Treatise on Ore Depos- 
 its, 270. 
 
 Covellite, mineral, 263. 
 
 Cream of tartar, re-agent, 93, 
 98; reducing power, 121. 
 
 Crucible charges, for argol, 121; 
 for charcoal, 122; for copper 
 carbonates, 183; for copper 
 oxides, 183; for copper sul- 
 phides, 184; for cream of tar- 
 tar, 121 ; for gold and silver in 
 galena, 179; large, 175; for lead 
 carbonates, 195; for lead in 
 galena, 180, 189. 190, 191, 193; 
 for lead oxides, 195; for lith- 
 arge, 116; for native copper, 
 182; for nitre, 122; for quartz, 
 sand or "dry" ores, 171; for 
 testing ores, 124; Low's, 177; 
 
 Ricketts', 122, 124, 176, 184, 
 191; Stone's. 178. 
 
 Crucible process, 133, 170; di- 
 rections for operating, 171; for 
 gold and silver ores, 138, 170; 
 theory of, 1 74. 
 
 Crucible tongs, 59. 
 
 Crucibles, alumina, 69; Batter- 
 sea, 70 ; black lead (graphite or 
 plumbago), charcoal-lined, 69; 
 clay, 70; "Colorado," 71; 
 French clay or "Beaufay," 69, 
 70; gold, 69; "Gramme," 71; 
 Hessian, iron, magnesia, plati- 
 num, 69; porcelain, 69, 78; 
 quick lime, 69; round, 70; 
 sand, 70; silver, 70; triangular, 
 70. 
 
 Crushers, Alden, Blake, Forster, 
 Lipsey, 18, 19. 
 
 Cupel, color tests, 247; moulds, 
 88; rake, 64; shovel, 04; tongs, 
 62. 
 
 Cupellation, 141, 152. 
 
 Cupels, 73; directions for mak- 
 ing, 74. 
 
 Cupreous, bismuth, 262; sul- 
 phato-carbonate of lead, 263, 
 265. 
 
 CupRic Oxide, mineral, 264. 
 
 Cuprite (or cuprous oxide), min- 
 eral, 180, 263. 
 
 Cups, annealing, 76. 
 
 Cyanide of potash, properties,. 
 96; re-agent, 93, 95. 
 
 Cyclopedia, Johnson's New Uni- 
 versal, 268. 
 
INDEX. 
 
 303 
 
 D 
 
 Dana, Manual of Geology, 270; 
 Manual of Mineralogy, ■ 371; 
 reference to, 267; System of 
 Mineralogy, 267, 270; Text- 
 book of Geology, 270. 
 
 Dark bed silvek ore, 130, 260. 
 
 Davtum, element, 12. 
 
 Dechenite, mineral, 265. 
 
 Decipium, element, 12. 
 
 Definitions, of analysis, 13;-- of 
 assaying, 18. 
 
 Dendritic silver, 259. , 
 
 Denver fire clay crucibles, 
 71. 
 
 Descloizite, mineral, 265. 
 
 Desulphurizing action, of bi- 
 carbonate of soda, 94; carbon- 
 ate of ammonia, 99; cyanide 
 of potash, 96; iron, 105, 189; 
 litharge, 104. 
 
 Determination of moisture in 
 an ore, 255 ; oxidizing power of 
 nitre, 115, 122; reducing pow- 
 ers of argol, 121; cliarcoal, 122; 
 cream of tartar, 121; ores, 116, 
 123; reducing agents, 115, 121. 
 
 Di-CHROMATE, potassic, 108. 
 
 Dictionary of Chemistry, Watts', 
 268. 
 
 DiDYMiuM, element, 12. 
 
 Directions foe bullion balances, 
 37; crucible process, 171 ; cupel- 
 lation, 154; filtering, 212; 
 making cupels, 74; operating 
 Hoskins' furnace, 48 ; operating 
 
 Myers' furnace, 52; sampling 
 ores, 134. 
 
 Dishes, roasting, 71. 
 
 Distilled water, chlorine in, 
 106; re-agent. 106. 
 
 Dividers, 24. 
 
 Domeykite, mineral, 283. 
 
 Douglas & Prescott's Qualita- 
 tive Analysis, 269. 
 
 Dry re-agents, list of, 93. 
 
 Dysceasite, mineral, 259. 
 
 E 
 
 Eggleston, reference to, 285. 
 
 Eggleston's Weights, Measures 
 AND Coins, 274. 
 
 Elderhorst's , Blow-pipe Anal- 
 ysis, 271. 
 
 Electrum, mineral, 257, 259. 
 
 Elements, lists of, 11, 12. 
 
 Elements of Chemistry, Mil- 
 lee's, 268. 
 
 Eliot and Storee's Qualitative 
 Analysis, 269. 
 
 Bmbolite, mineral, 259. 
 
 Enaegitb, mineral, 261, 263. 
 
 Engineering and Mining Jour- 
 nal, references to, 134, 206, 
 243. 
 
 English and French weights, 
 equivalents of, 285. 
 
 Erbium, element, 12. 
 
 Erubescite, mineral, 262. 
 
 BusTis.W. E. C, reference to, 211. 
 
 Explanation of assay ton 
 weights, 41. 
 
304 
 
 INDEX. 
 
 F 
 
 " Fbathering," 155. 
 
 Ferric sebquioxide, 114. 
 
 Fekrocyanide, potassic, re- 
 agent, 109. 
 
 Feruo tellurite, mineral, 258, 
 261. 
 
 Ferrous sulphate, re,agent, 111; 
 sulphide, re-ageut, 111. 
 
 Filings, iron, re-agent, 105. 
 
 Filtering, directions for, 212. 
 
 Filter paper, 83 ; stands, 91. 
 
 Fire clay, in clay lute, 114. 
 
 "Flashing," 156. 
 
 Flasks, 80 ; parting or boiling, 79. 
 
 Fletcher's gas furnace, 44, 
 191. 
 
 Floors, muffle, 69. 
 
 Flour, re-agent, 93, 98. 
 
 Flour gold, 129, 257. 
 
 Fluorine, element, 11. 
 
 Fluor sp.\r. mineral, 178. 
 
 Fluxes, acid 101; basic, 99; bi- 
 carbonate of soda, 93, 24; 
 black flux substitute, 93, 98; 
 borax, 93, 96 ; carbonate of pot. 
 ash, 93, 95 ; cyanide of potash, 
 93, 95 ; flour, 93, 98 ; glass, 101 ; 
 litharge, 94, 103 ; metallic, 104 ; 
 neutral, 96; nitre, 99; sand, 
 101; scales for, 28; silica, 101; 
 Stone's universal, 178. 
 
 Fluxing pots, 70. 
 
 Foil, lead, reagent, 102; lead, 
 silver in, 120 ; silver, re-agent, 
 105. 
 
 Foliated tellurium, mineral, 
 
 257, 267. 
 Form for certificate of assay, 
 
 275. 
 
 FORSTER CRUSHER, 19. ' 
 FOYE'S MINERAL TABLES, 271. 
 FrAZER'S MINERAL TABLES, 271. 
 
 Free gold, 129, 257; assay of 
 
 in ores, 203. 
 Free ■ silver, 259 ; assay of in 
 
 ores, 203. 
 " Freezing," 159. 
 Freieslebenite, mineral, 259, 
 
 266. 
 French clay crucibles, 69. 
 French or metric weights, 
 
 39,40; equivalents in English 
 
 •weights, 285 ; tables of, 283. 
 Fresenius' Qualitative and 
 
 Quantitative Analysis, 255, 269 ; 
 
 reference to, 255. 
 Frying pan, 87. 
 Fuel, metallurgy, Percy, 272. 
 Funnels, glass, 80; separatory, 
 
 80, 236. 
 Furnaces, 42 ; apparatus used in 
 
 68; Battersea, 53; Brown's, 
 
 55; Fletcher's, 44; Hoskins', 
 
 48; Judsou's, 54; Myers', 49; 
 
 tools for, 59; using gaseous 
 
 fuel, 43; using liquid fuel, 46, 
 
 using solid fuel, 53. 
 
 G 
 
 Galena or galenite, 185, 258, 
 261, 266; crucible charge for, 
 
INDEX. 
 
 305 
 
 179; iron in assay of, 105, 189; 
 methods for, 186 ; scoriflcation 
 charge for, 170. 
 
 Gallitjm, element, 12. 
 
 Gas furnaces, Fletcher's, 44, 19 1 . 
 
 Gas, hydrogen sulphide, re- 
 agent, 111. 
 
 Gauze, wire, 87. 
 
 " Gem-pi.ate," 66. 
 
 General chemistry, books on, 
 268; qualitative and quantita- 
 tive analysis, books on, 269; 
 science, books on, 268. 
 
 Geocronite, mineral, 261, 266. 
 
 Geology, books on, 270. 
 
 Glance, copper, 263; lead, 131; 
 silver, 180, 258; silver-copper, 
 131, 260, 264. 
 
 Glass and porcelain apparatus, 
 77 ; beakers, 80 ; borax, 93, 
 96 ; borax, preparation, 97 ; case 
 for pulp-scales, 29; flasks, 80, 
 funnels, 80; magnifying, 90; 
 mortars, 81; pipettes, 81; re- 
 agent, 101 ; stirring-rods, 80 ; 
 spatulas, 27. 
 
 Glasses, watch or clock, 31, 78. 
 
 Glucinum, element, 12. 
 
 Glycerine, for sulphuretted hy- 
 drogen water, 113. 
 
 Gold, amalgam, 257, 261; and 
 lead telluride, 257, 267 ; argen- 
 tiferous, 257, 259 ; assaying of, 
 129, 132; assaying of free, 203; 
 bullion assay, 239; chlorina^ 
 tion assay, 234; element, 11; 
 crucible process, 170; flour, 
 20 
 
 free, leaf, native, nugget, wire, 
 129, 257; in silver foil, 105; 
 Lock's work on, 272, minerals 
 in U. S., 257; minerals likely 
 to carry, 258; multiplication 
 table, 279 ; native, 129, 257, 261 ; 
 occurrence, 129 ; pan test or 
 "panning," 225; residues, 
 weighing of, 141, 165; tellu- 
 ride, 257 ; testing of silver-foil 
 for, 105 ; table of values of, 
 280 ; washing pans, 91, 227. 
 
 " Gold weights," 42, 240. 
 
 Gold and silver and lead tellu- 
 ride, 257, 266 ; assaying, 129, 
 182 ; beads, balances for weigh- 
 ing, 33 ; beads, weighing of, 
 141, 160 ; calculations, 141 , 166 ; 
 crucible process, 170; cupella- 
 tion, 141, 153 ; inquartation, 
 141, 164; metallurgy, books on, 
 373; multiplication table, 279 ; 
 occurrence, 139; parting, 141, 
 161 ; preparation of charge 
 141 I preparation of sample, 
 133; residue, weighing, 141, 
 165.; roasting, 142; scoriflca- 
 tion charges, 167; scoriflcation 
 process, 139; table of values, 
 280; telluride, 257,'259, 260. 
 
 Grain weights, 41. 
 
 " Gramme '' crucibles, 71 
 
 Gramme weights, 39, 40. 
 
 Gkanul.\ted lead, preparation, 
 102; re-agent, 94, 102; testing 
 for silver, 118. 
 
3o6 
 
 INDEX. 
 
 Gkaphic tellurium, mineral, 
 257, 260. 
 
 Gray COPPER, 129, 181, 260, 264; 
 argentiferous, 131. 
 
 Green carbonate of copper, 181, 
 264 ; copper ore, 264 ; lead ore, 
 266; malachite, 264; mount- 
 ain, 263, 261; vitriol. 111. 
 
 Grinding plate, 21; Mr. S. A. 
 Reed's, 23. 
 
 Gummed labels, 83, 133. 
 
 H. 
 
 Hammers, 84. 
 
 Hand-scales, 81. 
 
 Harrisite, mineral, 263. 
 
 Haut, reference to, 255. 
 
 Hart's Volumetric Analysis, 
 255, 270. 
 
 Heavy spar, mineral, 178. 
 
 Hematite, reagent, 114. 
 
 Henryite, mineral, 258, 261, 266. 
 
 Hessian crucibles, 69. 
 
 Hessite, mineral, 258, 259, 261. 
 
 HoLMiuM, element, 12. 
 
 Horn, silver, mineral, 130, 259 ; 
 spatulas, 27 ; spoons, 28. 
 
 Hoskins' assay furnace, 46. 
 
 Hydrate,, ammonic, re-agent, 
 108 ; potassic, re-agcnt, 108. 
 
 Hydric nitrate, re-agent, 107. 
 
 Hydrochloric acid, re-agent, 
 109. 
 
 Hydrogen ; element, 11 ; sul- 
 phide, preparation of as re- 
 agent, 111. 
 
 Hydro - sodic - carbonate, re- 
 agent, 93, 94. 
 
 Hydro - potassic - tartrate, re- 
 agent, 98. 
 
 Hydroxide, calcic, re-agent, 
 110. 
 
 Hyposulphite op sodium, re- 
 agent, 109, 238. 
 
 I. 
 
 Implements for pulverizing, 
 sampling, etc., 18. 
 
 Importance of average sam- 
 ples, 134. 
 
 Important silver ores, 130. 
 
 Indigo copper, mineral, 263. 
 
 Indium, element, 12. 
 
 Ingot moulds, 90. 
 
 Inquartation, 141, 164. 
 
 Introduction, 11. 
 
 Iodic silver (iodide of silver, 
 iodyrite), 131, 259. 
 
 Iodide of potash, re-agent, 109. 
 
 Iodine, element, 11. 
 
 Iridium, element, 11. 
 
 Iron and copjDer sulphide, sul- 
 phuret or pyrites, 129, 133, 262, 
 263; and silver sulphide, 260; 
 brief scheme for, 254 ; color on 
 cupel, 248; color on scorifier, 
 247 ; desulphurizing action, 
 105, 189; element, 11; filings, 
 105; mortars, 18; nails, 94,105; 
 oxide, 129; re-agent, 94, 105; 
 red oxide, 114; retorts, 93; 
 sulphate. 111 ; sulphide or sul- 
 
INDEX. 
 
 307 
 
 phuret, re-agent, 111; tests for, 
 251 ; wire, 04, 105. 
 -Ivory spatulas, 27. 
 
 Jamesonite, mineral, 266. 
 ■ Johnson's New Universal Cy- 
 clopedia, 2G8. 
 
 JosEiTE, mineral, 258, 261. 
 
 JuDSON's cupel tongs, 63; fur- 
 naces, 54; scoriflcation tongs, 
 62. 
 
 K. 
 
 Kerl's Metallurgy, 271; Works 
 on Assaying, 273. 
 
 KoBELLiTE, mineral, 266. 
 
 KusTEL, references to, 6, 130, 
 235, 237, 239; Roasting of Gold 
 and Silver Ores, 6, 130, 272. 
 
 L. 
 
 Labels, gummed, 82, 133. 
 
 Laboratory Manipulation, 
 books on, 270 ; mill-run, 231. 
 
 Lamborn's Metallurgy, 273. 
 
 Lamps, 87. 
 
 Lanarkite, mineral, 266. 
 
 Lanthanum, element, 12. 
 
 Lead acetate, 105 ; ■ and anti- 
 mony sulphide, 265 ; and cop- 
 per chromate, 265, 267; and 
 ■gold telluride, 365, 267; and 
 silver, antimonial sulphide of, 
 259,266; and silver, metallur- 
 gy, 272; and zinc vanadate. 
 
 265; arsenate, 266; assay, 186; 
 bismuth and antimony sul- 
 phide, 266; bismuth and sil- 
 ver sulphide, 358, 260, 265, 
 267; carbonate, mineral, 133, 
 186, 205; carbonate, re-agent, 
 105; carbonates, assay, 194; 
 color on cupel, 248; color on 
 scorifler, 247 ; copper and anti- 
 mony sulphide, 362, 365; cu- 
 preous-sulphato-carbonate, 263, 
 265; element, 11; foil, re- 
 agent, 102 ; foil, silver in, 120 ; 
 glance, 131 ; granulated, pre- 
 paration, 103; granulated, re- 
 agent, 94, 103; granulated, sil- 
 ver in, 118; metallurgy, 272; 
 minerals, 265 ; molybdate, 267 ; 
 native, 267; ore, white, 186, 
 365; ore, yellow, 367; ores, 
 265; ores, argentiferous, 131; 
 ores, assay, 186; ores, occur- 
 rence, 185; oxides, assay, 194; 
 phosphate of alumina and, 
 267; phosphate and chloride 
 of, 267; red oxide, mineral, 
 186, 266; red oxide, removal 
 from litharge, 103; sheet, re- 
 agent, 94, 103 ; sheet, silver in, 
 120; silver and bismuth sul- 
 phide, 358^ 260, 265, 267; sil- 
 ver and gold telluride, 857, 
 266; spar, 367; sugar of, 105; 
 sulph-antimonite, 366; sulph- 
 arseno-antimonite, 366 ; sul- 
 phate, mineral, 365; sulphato- 
 carbouate and tri-carbonate,266 
 
3o8 
 
 INDEX. 
 
 sulphates, assay, 186 ; sulphide 
 or sulphuret, assay, 186; sul- 
 phide or sulphuret, mineral, 
 131,185, 366; sulphide, iron in 
 assay of, 105, 189 ; telluride, 265, 
 266; tests for, 252; tungstate, 
 267 ; vanadate, 265 ; vitriol, 265 ; 
 white, re-agent, 105; yellow- 
 oxide, mineral, 266; yellow 
 oxide, re-agent, 103. 
 
 Leadhillite, mineral, 266. 
 
 Leaf gold, 129, 257; silver, 259. 
 
 Le Conte's Elements op Geol- 
 ogy, 270. 
 
 Ledcopyrites, mineral, 261. 
 
 llebek's assayer's gcide, 273. 
 
 Light ked silver ore, 130, 
 259. 
 
 Lime, sulphate of, 264. 
 
 Lime v^atbr, re-agent, 110, 
 
 LiONiTE, mineral, 258, 261. 
 
 LlPSEY CRUSHER, 19. 
 
 Lists aud references, 257. 
 
 Lists, copper minerals, 262; 
 dry re-agents for assaying, 93 ; 
 elements, 11, 12; gold miner- 
 als, 257; lead minerals, 265; 
 minerals carrying gold, 258; 
 minerals carrying silver, 261 ; 
 re-agents for analysis, 108 ; sil- 
 ver minerals, 258; useful 
 books, 268; wet re-agents for 
 assaying, 106. 
 
 Litharge, properties, 104; re- 
 agent, 94, 103; to free from 
 red oxide, 103; silver in, 115, 
 116. 
 
 Lithium, element, 11. 
 Lock's Work on Q-old, 272. 
 Lowe, F. A., reference to, 306. 
 Low's crucible charge, 177. 
 Lunar caustic, re-agent, 110. 
 Lute, clay, 114. 
 
 M. 
 
 Magnesium, element, 11. 
 
 Magnet, 90. 
 
 Magnifying glass, 90. 
 
 Magnolite, mineral, 258, 261. 
 
 Makin's Manual of Metal- 
 lurgy, 273. 
 
 Malachite, 264; blue, 262; 
 green, 264. 
 
 Manganese, black or di-oxide, 
 108 ; brief scheme for, 254 ; col- 
 or on cupel, 248; element, 11. 
 
 Manipulation, Laboratory, 
 books on, 270. 
 
 Massicot, mineral, 266. 
 
 Matrasses, 79. 
 
 Melaconite, mineral, 180, 258, 
 261, 364. 
 
 Mercury, chloride, 110 ; element, 
 11 ; metallic, 110 ; native, 361 ; 
 re-agent, 110. 
 
 Metallic, copper, mercury, 
 zinc, 110; scales, 205, 207. 
 
 Metallurgy AND Mining, books 
 on, 271. 
 
 Methods, assay for copper ox- 
 ides and carbonates, 183 ; assay 
 for copper sulphides, 183 ; as- 
 say for galena, 186; assay for 
 
INDEX. 
 
 309 
 
 lead oxides and carbonates, 
 194; assay for native copper, 
 183; of copper analysis, 210; 
 special, 201. 
 
 Metric btstem, books on, 274. 
 
 Metric weights, equivalents 
 in English, 285; tables of, 283. 
 
 Mtabgyritb, mineral, 130, 259. 
 
 Miller's Elements of Chem- 
 istry, 208. 
 
 Mill run, laboratory, 221. 
 
 Mimetite, mineral, 266. 
 
 Mineralogy, books on, 270. 
 
 Minerals, assaying of, in an ore 
 201; copper, 263; gold, 257; 
 lead, 265 ; likely to carry gold, 
 258 ; likely to carry silver, 261 ; 
 silver 258. 
 
 Miners' gold-washing pans, 91, 
 227. 
 
 Mining law, books on, 274. 
 
 Minium, mineral, 186, 266. 
 
 Miscellaneous apparatus, 81. 
 
 Mitchell, references to, 6, 37, 
 46, 59, 74, 103, 104, 184, 197, 
 243, 246, 247. 
 
 Mitchell's Manu.^l op Practi- 
 cal Assaying, C, 273. 
 
 Moisture in ores, determination 
 of, 255. 
 
 Molybdate op lead, mineral, 
 267. 
 
 Molybdenum, element, 11. 
 
 MoRPiT's Chemical Manipula- 
 tions, 270. 
 
 Moktak, amalgamation, 91, 223. 
 
 Mortars and pestles; glass, 
 81; iron, 18; porcelain, 81. 
 
 Mosandrium, element, 12. 
 
 Moulds; cupel, 88; ingot, 90; 
 scorifler, scorification or slag, 
 65. 
 
 Mountain blue, 262, 263'; green, 
 263, 264. 
 
 MuppLE floors, 69; hoe or rake 
 64 ; scraper, 67 ; shovel, 64. 
 
 Muffles, 68. 
 
 MuLLERiTE, mineral, 257, 261, 
 266. 
 
 Multiplication Table por 
 Gold and Silver, 279. 
 
 Muriate of barium, 109; of 
 copper, 262; of silver, 259. 
 
 Muriatic acid, 109. 
 
 Myers' " Jewel " Assay Appa- 
 ratus, 49. 
 
 N 
 
 Nagyagite, mineral, 257, 261, 
 267. 
 
 Nails, iron, re-agent, 94, 105. 
 
 Native antimony, 261 ; arsenic, 
 258, 261; bismuth, .258, 261; 
 copper, 180, 261, 264; copper, 
 assay, 183; gold, 129, 257, 261; 
 lead, 267; mercury, 361; sil- 
 ver, 258, 259; tellurium, 258, 
 261. 
 
 Needle ore, mineral, 262. 
 
 Nickel, cobalt and copper, sul- 
 phide, 263 ; element, 11. 
 
 Nitrate op silver, re-agent, 
 110. 
 
3IO 
 
 INDEX. 
 
 Nitre, oxidizing power, 115, 
 133 ; re-agent, 94, 99. 
 
 NiTitio ACID, preparation of va- 
 rious strengths, 103; re-agent, 
 107, 110; to free from chlorine, 
 107. 
 
 NiTRor.EN, element 11. 
 
 North's Practical Assaying, 
 273. 
 
 NoRWEGiuM, element, 12. 
 
 Note-books, 81, 133. 
 
 NuoaET GOLD, 129, 257. 
 
 o. 
 
 Ochre, plumbic, 260. 
 
 Occurrence of ores, copper, 
 180 ; gold, 129 ; gold and silver, 
 129; lead, 185; silver, 130. 
 
 Oertling's bullion balance, 
 35. 
 
 Oil cloth for sampling, 82. 
 
 Oil of vitriol, re-agcnt, 113. 
 
 Order op work in scorifica- 
 tion process, 141. 
 
 Ore, argentiferous gray copper, 
 131; arsenical silver, 259; as- 
 saying of minerals in, 201 
 azure copper, 203; brittle sil 
 ver, 130 ; dark red silver, 130 
 260 ; gray copper, 181, 260, 264 
 green copper, 264 ; green lead 
 266; light red silver, 130, 2.59 
 needle, 262; purple copper, 
 263 , variegated .copper, 262 
 vyhite lead, 186, 265; yellow 
 lead, 267. 
 
 Ores, analysis of copper, 210; 
 argentiferous lead, 131; "car- 
 bonate," 129; charge for test- 
 ing, 124; "chloride," 131; 
 chlorination assay of gold, 234 ; 
 containing free gold or silver, 
 assaying of, 203; copper, 262; 
 copper, assay, 181 ; copper, oc- 
 currence, 180 ; determination of 
 moisture in, 255 ; directions for 
 sampling, 135; gold, 129; gold, 
 assay, 133; gold, occurrence, 
 129 ; gold and silver, 129 ; gold 
 and silver, assay, 133 ; gold and 
 silver, occurrence, 129 ; import- 
 ant silver, 130; lead, 185; lead, 
 assay, 180; lead, occurrence, 
 185; pulverizing, 18, 21, 137; 
 reducing powers of, 116, 123; 
 silver, 130; silver, assay, 138; 
 .silver, occurrence, 130; tellu- 
 rium, 129 ; volumetric analysis 
 of copper, 220. 
 
 Osmium, element, 12. 
 
 Outfit, assaying, 276. 
 
 Overman's Assaying, 273. 
 
 Oxide, antimony, 260; copper, 
 180, 183, 264; copper, black, 
 180, 264; copper, red, 180, 203; 
 cupriei, 264 ; cuprous, 263 ; Iron, 
 129 ; irou; red, 114 ; lead, led, 
 mineral, 186, 266; lead, red, to 
 remove from litharge, 103; 
 lead, yellow, mineral, 266; 
 manganese, black, 108; yel- 
 low, re-agent, 103; uranium, 
 264. 
 
INDEX. 
 
 3" 
 
 Oxides, copper, assay, 183; iron, 
 silica for, 170; lead, assay, 194. 
 
 Oxidizing action of bi-carbon- 
 ate of soda, 94 ; action of nitre, 
 99; power of nitre, 115, 123. 
 
 OxY-CHLORiDE OP COPPBK, min- 
 eral, 203. 
 
 Oxygen, element, 11. 
 
 Palladium, color on cupel, 248 ; 
 element 11. 
 
 Pan test or "panning" for 
 gold, 225. 
 
 Pans, frying, 87; miners' gold- 
 washing,91,227 ; zinc sifting,2G. 
 
 Papers, black glazed, 82; blot- 
 ting, 83; brown or Manilla, 
 83; filter, 83; tissue, 83. 
 
 " Parting," 141J1G1. 
 
 Parting-plasks, 79. 
 
 Percy's Metallurgy, 272. 
 
 Permanent furnaces, 59. 
 
 Petzite, mineral, 257, .259, 261. 
 
 Philippium, element, 13. 
 
 Phillips' Assayers' Companion, 
 373. 
 
 Phosphate and chloride of 
 lead, 267 ; of alumina and lead, 
 207 ; of copper, 264 ; of urani- 
 um and copper, 264. 
 
 Phosphorus, element, 12. 
 
 Pincers, 83. 
 
 Pipettes, 81. 
 
 • Plate, annealing, 76; gem, 66; 
 pouring, 65 ; pulverizing, 21. 
 
 Platinum ; color on cupel, 248 ; 
 dish, 214; element, 12; spatu- 
 las, 27. 
 
 Plattner's Blow-pipe Analy- 
 sis, 271. 
 
 Plumbic, acetate, re-agent, 105; 
 carbonate, re-agent, 105; mon- 
 oxide, re-agent, 103; ochre, 
 266. 
 
 Plumbogummite, mineral, 267. 
 
 Plympton's Blow-pipe Deter- 
 mination, 371. 
 
 Pokers, 67. 
 
 PoLYBASiTE, mineral, 130, 359. 
 
 Porcelain and glass appara- 
 tus, 77 ; casserole, 81 ; cruci- 
 bles or- capsules, 78, 161 ; mor- 
 tars, 81 ; spatulas, 27. 
 
 Potash carbonate, 93, 95; caus- 
 tic or hydrate, 108; cyanide, 
 
 93, 95 ; bi or di-chromate, 108; 
 bi-tartrate, 98, 131 ; ferrocya- 
 nide, 109 ; iodide, 109 ; nitrate, 
 
 94, 99, 115, 133; sulphocya- 
 ni'de. 111; yellow prussiate, 
 109. 
 
 Potassium, element, 12. 
 
 Pouring plates, 65. 
 
 Precipitated silica, re-agent, 
 101. 
 
 Preface, 5. 
 
 Preliminary work, 115. 
 
 Preparation of borax glass, 
 97 ; charge in scorification pro- 
 cess, 141 ; granulated lead, 103 ; 
 samples, 133 ; various strengths 
 of nitric acid, 163. 
 
312 
 
 INDEX. 
 
 Process, crucible, 133, 170; 
 scorification, 183, 139. 
 
 Proto-chloride op tin, re- 
 agent, 111. 
 
 Procstite, mineral, 259. 
 
 Prussiate op potash, yellow, 
 109. 
 
 PsEUDOMALACHiTB, mineral, 364. 
 
 Pulps, scales for, 28. 
 
 Pulverizing of ores, 18, 21, 
 137; sampling, etc., imple- 
 ments for, 18, plate and rub- 
 bers, 21 ; plate and rubbers, 
 manner of using, 38. 
 
 Purple copper ore, 262. 
 
 Pyrargyrite, mineral, 260. 
 
 Pyrite, mineral, 258, 261. 
 
 Pyrites, argentiferous, 133 ; cop- 
 per, 363; iron and copper, 129, 
 183. 
 
 Pyromorphitb, mineral, 267, 
 
 Q 
 
 Qualitative Analysis, Douglas 
 and Prescott's, 369 ; Eliot and 
 Storer's, 269 ; Presenius', 255 ; 
 general, books on, 369. 
 
 Qualitative tests, 249; car- 
 bonates, 249 ; copper, 251 ; iron, 
 351; lead, 353; silver, 353; 
 sulphates, 250 ; sulphides, 250 ; 
 tellurides, 250. 
 
 Quantitative ANALYSi8,Cairns', 
 369; Classen's, 269; Fresenius', 
 255; general, books on, 269; 
 Rammelsberg's, 369; special, 
 books on, 369 ; Wohler's, 369. 
 
 R 
 
 Rake, cupel, 64. 
 
 Rammelsberg's Quantitative 
 Analysis, 269. 
 
 Re-agents, dry, for assaying, 93 ; 
 for analysis, 108 ; in scorificar 
 tion process, 140; testing of, 
 115; wet, for assaying, 106. 
 
 Realgar, mineral, 261. 
 
 Red oxide op copper, 180, 363 ; 
 iron, 114; lead, mmeral, 186, 
 326; lead, removal of, from 
 litharge, 103. 
 
 Reducing power op, argol, 131 ; 
 charcoal, 123; cream of tartar, 
 121; ores, 116, 123; reducing 
 agents, 115, 121. 
 
 Reference books on chemis- 
 try, 268. 
 
 Repebbnces and lists, 357. 
 
 Reperences to Am. Inst, of Mln. 
 Eng., 311; Attwood, 337; Aus- 
 tin, K S., 184, 345; Bodemann 
 and Kerl, 184 ; Dana, 267 ; Eg. 
 gleston, T., 285 ; Eng. and Min 
 Jour, 134, 206, 243; Eustis, W, 
 E.C.,211 ; Fresenius, 255; Hart 
 355; Kustel, 6, 130, 335, 237^ 
 239; Lowe, F. A., 206; Mitch 
 ell, 6, 37, 46, 59, 74, 103, 104, 
 184, 197, 343, 346, 347; North, 
 347; Ricketts, 6, 59, 133, 134, 
 155, 176, 184, 191, 304, 337 
 Smith, J. A., 267 ; Sutton, 355 
 Triplett, 247, 348. 
 
 Report on Colorado Miner- 
 als, 267. 
 
INDEX. 
 
 313 
 
 Rbpobt on Silver Bullion 
 Wastage, 239 
 
 Residues, gold, weighing of, 
 141, 165. 
 
 Ketokting in scovifiers, 224. 
 
 Retorts, iron, 92. 
 
 Rhodium, element, 12. 
 
 RiOKETTS, charge for copper sul- 
 phides, 184 ; charge for galena, 
 191; charge for nitre, 122; 
 charge for pyrites, 17(i ; Notes 
 on Assaying, 6, 273 ; references 
 to, 6, 59, 122, 124, 155, 176, 184, 
 191, 204, 237. 
 
 Ring stand, 86. 
 
 Roasting, carbonate of ammo- 
 nia used in, 143 ; charcoal used 
 in, 144; of ores in crucible pro- 
 cess, 171; dishes, 71; of ores in 
 scorification process, 141 ; sili- 
 ca used in, 143. 
 
 Rolls, 90. 
 
 RoscoE and Shorlemmer's, Chem- 
 istry, 268; Elementary Chem- 
 istry, 269. . 
 
 Round cbucibles, 70. 
 
 RuBBEK, sheet or cloth, 82. 
 
 Rubbing plate, 21. 
 
 Rubidium, element, 12. 
 
 Ruby silver, mineral, 130, 259, 
 260. 
 
 Ruddle, 114. 
 
 Ruthenium, element, 12. 
 
 Rutley's Study of Rocks, 270. 
 
 Salt, c6mmon, re-agent, 94, 99. 
 
 Saltpetre, re-agent, 94, 99 
 Salts, tin, re-agent, 111. 
 Samarium, element, 13. 
 Sample bottles, 77, 134; boxes, 
 
 82, 134; preparation of, 133; 
 
 shovels,' 24. 
 Samplers, 24. 
 
 Samples, to obtain average, 134. 
 Sampling op base bullion, 245. 
 Sand baths, 87; crucibles, 70; 
 
 in accidents to muffles, 150j 
 
 re-agent, 101. 
 Scales and balances, 28; hand, 
 
 31 ; pulps and fluxes, 28. 
 Scales, metallic, 205, 207. 
 Scandium, element, 12. 
 ScHAPBACHiTE, mineral, 260, 267. 
 Scheme for silica, iron ANb 
 
 MANGANESE, 254. 
 
 ScHiRMERiTE, mineral, 260, 267. 
 
 Science, general, books on, 268. 
 
 Scissors, 90. 
 
 Scorification, color tests, 246; 
 moulds, 05 ; tongs, Judson's, 62. 
 
 Scorification process, 133, 139 ; 
 borax glass in, 140; buttons 
 from, 148 ; calculations, 141, 
 166; charges, 167; cupellation, 
 141, 153; granulated lead in, 
 140; inquartation, 141, 164; 
 order of work, 141 ; parting, 141, 
 161 ; preparation of charge, 141 ; 
 re-agents used for, 140 ; roasting 
 of oresin,141 ; scorification, 141, 
 146 ; scorifiers from, 150 ; silica 
 in, 141 ; slag from, 149 ; theory 
 ' of, 140 ; weighing gold and 9il- 
 
314 
 
 INDEX. 
 
 ver bead, 141, 160; weighing 
 
 gold residues, 111, 165. 
 ScoKiFiEU, color tests, 247 ; 
 
 moulds, Gj; tongs, 61. 
 ScoRipiEHS, 72; "retorting" in, 
 
 224. 
 
 SCKAPER, MUFFLE, 67. 
 
 Seleniu.m, element, 13. 
 
 SEPAR.4.T0BY FUNNEL, 80, 236. 
 
 Sesquioxidb, fekric, re-agent, 
 114. 
 
 She.\bs, 90. 
 
 Sheet lead, re-agent, 94, 102; 
 testing for silver, 120; rubber, 
 for sampling, 83. 
 
 Shovels, cupel, 64; sample, 34. 
 
 Sieves, 26 ; box, 26. 
 
 Sifting of ores, 137 ; pans, 26. 
 
 SiLjCA, acid flux, 101 ; brief 
 scheme for, 254; in scoriflca,- 
 tion process, 140, 143 ; precipi- 
 tated, 101 ; re-agent, 94, 101. 
 
 Silicate op copper, mineral, 
 26a 
 
 Silicic Di-oxiDE, re-agent, 101. 
 
 Silicon, element, 12. 
 
 Silver and antimony sulphide, 
 130, 259, 260 ; and copper sul- 
 phide, 131, 260, 264; and gold, 
 metallurgy, 272 ; and gold mul- 
 tiplication table, 279; and gold 
 values, table of, 280; and gold 
 telluride, 257, 259, 260; and 
 gold ores, assaying, 132; and 
 iron sulphide, 260; and lead, 
 antimonial sulphide of, 259, 
 266 ; and lead, metallurgy, 273';'' 
 
 antimonial, 130, 259, 260; an- 
 timony and arsenic sulphide, 
 130, 259 ; arsenical, 259 ; assay, 
 133 ; assaying of ores contain- 
 ing free, 203 ; bismuth, 260, 
 267 ; bismuth and lead sul- 
 phide, 258, 260, 265, 267 ; black, 
 260; brittle, 130, 260; bromic 
 or bromide of, 131, 358; bull- 
 ion, report on wastage, 339 ; 
 chloride, 131, 359 ; chlorina- 
 tion test for, 337; chloro-bro- 
 mide, 259; copper glance, 131, 
 360, 264; dark red, 130, 260; 
 dendritic, 259 ; element, 13; 
 fahlore, 131; foil, gold in, 105; 
 foil, re-agent, 94, 105 ; free, 259 ; 
 glance, 130, 258 ; gold and lead 
 telluride, 357, 266; horn, 130, 
 359; in granulated lead, 115, 
 118; in lead foil, 130; in lith- 
 arge, 115,116; iodic or iodide 
 of, 131, 359 ; leaf, 359 ; lead and 
 bismuth sulphide, 358, 260, 
 265, 267; light red, 130, 259; 
 metallurgy, 272 ; minerals car- 
 lying silver, 300; minerals in 
 U. S.,258; muriate, 259; native, 
 258 ; nitrate, re-agent, 110 ; ores, 
 130; ores,' assaying, 133; ores, 
 important, 130 ; ores, occur- 
 rence, 130; ruby, 130, 259, 260; 
 spatulas, 27 ; sulphide or sul- 
 phuret, 130, 258; telluric or 
 telluride of, 259 ; test for, 253; 
 testing of granulated lead for, 
 118 ; testing of litharge for, 
 
INDEX. 
 
 315 
 
 116 ; testing of sheet lead for, 
 120 ; vitreous, 258 ; wire, 259. 
 
 SlLVBKSMITH'S HaND-BOOK FOR 
 ASSAYERS, 274. 
 
 Slag from scorification process, 
 
 149; moulds, Co. 
 Smaltite, mineral, 261. 
 Smitu, J. A., reference to, 267; 
 Report on Colorado Minerals, 
 267. 
 Soda, bi-earbonate of, 93, 94. 
 SoDic bi-borate, re-agent, 93, 96 ; 
 chloride, 99 ; hyposulphite,.109, 
 238. 
 Sodium, element, 12. 
 Spak-, calc, 178 ; fluor, 178 ; 
 
 heavy, 178 ; yellow lead, 367. 
 Spatulas,- 27. 
 
 Special directions for bullion 
 balances, 37 ; methods, 201 ; 
 quantitative analysis, books on 
 269. 
 Sphalerite, mineral, 258, 261. 
 " Spitting," 157. 
 Spoons, horn, 28. 
 "Sprojiting," 157. 
 Stand, Alter, 91 ; ring, 86. 
 Stannotis chloride, ra-agent, 
 
 111. 
 Steel alphabets and figures, 90 ; 
 
 spatulas, 27. 
 Stephanite, mineral, 130, 260. 
 Sternbergite, mineral, 260. 
 Stetefelditb, mineral, 131, 260. 
 Stirring rods, glass, 80; wire, 
 
 142. 
 Stoltzite, mineral, 267. 
 
 Stone's universal flux, 178. 
 Stoves, 87. 
 
 ■ Stromeyebite, mineral , 13 1 , 26a, 
 
 234. 
 Strontium, element, 12. 
 Sublimate, corrosive, reagent, 
 
 110. 
 Sugar of lead, re-agent, 105. 
 
 SULPH- ANTIMONITE OP LEAD, 
 
 mineral, 266. 
 
 SULPH-ARSENITE OF COPPER, 
 
 j mineral, 268, 264. 
 
 SULPH - ARSBNO .- ANTIMONITE OF 
 
 LEAD, mineral, 266. 
 
 Sqlphatbs, copper, 262, 268; 
 iron, HI; lead, 26.5; lime, 264- 
 test for, 350. 
 
 Sulphato-carbon-AlTE, and tri- 
 carbonate of lead, 266. 
 
 SuLPHiDBS or sclpiiurets. au- 
 riferous, 129; bismuth, silver 
 and lead, 258^ 360, 265, 267; 
 cobalt, nickel and copper, 263 ; 
 copper, 181, 203; copper and 
 iron, 181, 38i, 303 ; copper, lead 
 and, antimony, 303, 265; fer- 
 rous, re-agent. 111; iron, re- 
 agent, 111; iron and copper, 
 181; lead, 131, 266; lead and 
 antimony, 265 ; lead, bis- 
 muth, and antimony, 366; lead, 
 iron in assay of, 189 : roasting 
 of, 143, 171; silver, 130, 358; 
 silver and antimony, 130, 259, 
 260; silver and copper, 131, 
 360, 364 ; silver and iron, 260 ; 
 silver and lead, antimonial. 
 
3i6 
 
 INDEX. 
 
 2.)9, 266 ; silver, antimony and 
 arsenic, 259 ; test for, 250 ; zinc, 
 133. 
 
 Sdi-phocyanide op potassium, 
 re-agent. 111. 
 
 ScLPHun, element, 12; vapors, 
 color of, 246. 
 
 Sulphuretted hydrogen, prep- 
 aration, 111. 
 
 Sulphur ETS, auriferotjs, 129. 
 
 Sulphuric acid, re-agent, 113. 
 
 SuTTOJf, reference to, 255. 
 
 Sutton's Volumetric Analysis, 
 255, 270. 
 
 Stlvanite, mineral, 257, 260, 
 261. 
 
 Tables, 279; avoirdupois wgts., 
 281; apotliecaries' 'Wgts., 283; 
 assay ton weights in grammes, 
 grains, etc., 286; equivalents 
 of English and French weights, 
 285 ; French or metric weights, 
 283; multiplication for gold 
 and silver, 279 ; Troy weights, 
 282; values of gold and silver, 
 380; weights, 281. 
 
 Tantalum, element, 12. 
 
 Tartar, cream of, re-agent, 98. 
 
 Technology, Chemical, Wag- 
 ner's, 268. 
 
 Telluric silver, mineral, 259. 
 
 Tellukides, by crucible pro- 
 cess, 178 ; by scorification pro- 
 cess, 169 ; gold, 257 ; gold and 
 lead, 257, 267 ; gold and silver. 
 
 257, 259, 360; gold, silver and 
 lead, 257, 366; lead, 265, 266; 
 silver, 259 ; test for, 250. 
 Tellurite, mineral, 358, 261. 
 Tellurium, black, 257, 267; 
 color on scorifier, 247; ele- 
 ment, 12; foliated, 2.57, 267; 
 graphic, 257, 260 ; native, 358, 
 361 ; ores, 139 ; yellow, 257, 260. 
 
 Tellurpyrite, mineral, 258, 
 261. 
 
 Tennantite, mineral, 264. 
 
 Terbium, element, 12. 
 
 Testing of distilled water for 
 chlorine, 106 ; granulated lead 
 for silver, 115, 118; litharge for 
 silver, 115, 116; re-agents, 115; 
 sheet lead for silver, 115, 120; 
 silver foil for gold, 105. 
 
 Tests, chlorination for silver, 
 237; cupel color, 247; scorifi- 
 cation color, 246 ; scorifler col- 
 or, 247; qualitative for car- 
 bonates, chlorides, copper, 
 iron, lead, silver, sulphates, 
 sulphides, tellurides, 349. 
 
 Test-tubes, 79. 
 
 Tetradymite, mineral, 258, 261. 
 
 Tetrahedrite, mineral, 181, 
 258, 260, 264. 
 
 Text-books on theoretical chem- 
 istry, 268. 
 
 Thallium, element, 12. 
 
 Theory op crucible process, 174 ; 
 scorification process, 140. 
 
 Thorium, element, 12. 
 
 Thulium, element, 12. 
 
INDEX. 
 
 317 
 
 Tm, color on cupel, 248; ele- 
 ment, 12; proto-cliloride, or 
 "tin salts," 111. 
 
 Tissue paper, 83. 
 
 Titanium, element 13. 
 
 Tongs, crucible, 59 ; cupel, 63 ; 
 scorifler, 61. 
 
 Tools, fdrnace, 59. 
 
 TORBERNITB, mineral, 264. 
 
 Treatise on Chemistry, Ros- 
 coe and Schorlemmer's, 368; 
 Ore Deposits, Cotta's, 270. 
 
 Triangle, wire, 86. 
 
 Triangular crucibles, 70. 
 
 Triple sulphuret of copper, 
 lead and antimony, 363, 265. 
 
 Triplett, references to, 247, 
 348. 
 
 Triplett's How to Assay, 374. 
 
 Troemnbr's bullion balances, 
 33-4-5 ; pulp scales, 39. 
 
 Troy weights, tables of, 383. 
 
 Tubes, test, 79. 
 
 Tungstate op lead, mineral, 
 
 367. 
 Tungsten, element, 13. 
 
 U 
 
 United States, minerals found 
 in; copper, 363; gold, 257; 
 lead, 265 ; silver, 358. 
 
 Universal flux. Stone's, 178. 
 
 Uranium and copper, phosphate, 
 264 ; element, 13 ; oxide, 264. 
 
 Uranochalcite, mineral, 264. 
 
 Useful books, list of, 268. 
 
 Values of gold and silver, 
 
 table of, 280. 
 Vanadate op lead, 365; and 
 
 zinc, 265. 
 Vanadium, element, 12. 
 Variegated copper ore, 262. 
 Vauquelinitb, mineral, 265, 367. 
 "Vegetating," 157. 
 Vitreous copper, 263; silver, 
 
 258. 
 Vitriol, blue, 268; copper, 263; 
 
 green, 111; lead, 265; oil of, 
 
 113. 
 Volumetric Analysis of Cop- 
 per Ore, 220; Hart's, 255, 270; 
 
 Sutton's, 255, 270. 
 
 w 
 
 Wade's Mining Law, 274. 
 
 Wagner's Chemical Technol- 
 ogy, 368. 
 
 Wash-bottle, 78. 
 
 Wash, chalk, 114. 
 
 Wastage, Silver Bullion, Re- 
 port on, 239. 
 
 Watch-glasses, 31, 78. 
 
 Water, ainmonia, 108 ; distilled, 
 chlorine in, 106 ; lime, llO ; re- 
 agent, 106; sulphuretted hy- 
 drogen, 111. 
 
 Watts' Dictionary of Chemis- 
 try, 368. 
 
 Wehrlite, mineral, 358, 361. 
 
 Weighing gold and silver beads. 
 
3i8 
 
 INDEX. 
 
 141, 160 ; gold and silver beads, 
 balances for, 32 ; gold residues, 
 141, 1G5. 
 
 Weights, 39; and measures, Eg- 
 gleston's, 274 ; apothecaries', 
 tables, 283 ; assay ton, 40; assay 
 ton, explanation of, 41; assay 
 ton, in grammes, grains, etc., 
 286; avoirdupois, tables, 281; 
 equivalents of French and 
 English, 285; French, metric 
 or gramme, 39, 40 ; French or 
 metric, tables, 283; "gold," 42, 
 240; grain, 41; tables of, 279; 
 Troy, tables, 282. 
 
 Wet re-agents fob assaying, 
 106. 
 
 White lead ore, 186, 265; re- 
 agent, 105. 
 
 Whitneyite, mineral, 265. 
 
 Williams' Chemical Manipu- 
 lations, 270. 
 
 Wilson's Mining Laws of U. S., 
 274. 
 
 Window glass, as re-agent, 101. 
 
 Wire gauze, 87; gold, 129, 257; 
 iron, re-agent, 94, 105; silver, 
 359; stirring, 142; triangle, 86. 
 
 Wohler's Mineral Analysis, 
 
 269. 
 Wood charcoal, properties, 99 ; 
 
 re-agent, 94, 99; reducing 
 
 power, 122. 
 Work, order of, in scorification 
 
 process, 141 ; preliminary, 115. 
 WuLFENiTB, mineral, 267. 
 
 Yellow lead ore or spar, 267 
 oxide of lead, mineral, 266 
 oxide of lead, re-agent, 103 
 prussiate of potash, re-agent, 
 109; tellurium, 260. 
 
 Ytterbium, element, 13. 
 
 Yttrium, element, 12. 
 
 Zinc and copper carbonate, 362; 
 and lead vanadate, 265 ; blende, 
 argentiferous, 132 ; color on 
 cupel, 248 ; color of vapors, 
 246; element, 12; in battery, 
 110, 216 ; metallic, re-agent, 
 110 ; sifting-pans, 26 ; sulphide 
 or sulphuret, 132. 
 
 Zirconium, element, 13. 
 
Selections from the Publications 
 
 OF 
 
 yANSEN, McCLURG & CO. 
 
 GOLDEN POEMS. By British and American 
 
 Authors. Edited by Peanois P. Browne. Crown 8vo. EicWy 
 bound. Cloth, Full Gilt. Price, $S.50. Morocco Antiqne— Price, $5.00. 
 
 GOLDEN THOUGHTS. From the Words of 
 Leading Orators, Divines. Philosophers, States- 
 men and Poets. By Eev. S. P. Link. Crown 8to. Richly bonnd 
 Cloth, Pull Gilt. Price, $2.50. Morocco Antique— Price, $.5.00. 
 
 LIFE OF MOZART. From the German of 
 
 Louis Nohl. By John J. Lalok. With Portrait. Price, $1.25. 
 
 LIFE OF BEETHOVEN. From the German 
 
 of Louis Nohl. By John J. Lalob. With Portrait. Price, $1.25. 
 
 LIFE OF HAYDN. From the German of 
 
 Louis Nohl. By Geogb P. Upton. With Portrait. Price, $1.25. 
 
 MUSIC-STUDY IN GERMANY. By Miss Amy 
 
 Fat. Price, $1.25. 
 
 A SUMMER IN NORWAY. By Hon. J. D. Caton. 
 
 Portrait and Illustrations. Price, $1.75. 
 
 TRUTHS FOR TO-DAY. (Sermons.) By Prof. 
 
 David Swing. 1st Series— Price, $1.50. 2nd Series— Price, $1.60. 
 
 MOTIVES OF LIFE. By Professor David Swing. 
 
 Price, $1.00. 
 CLUB ESSAYS. By Prof. David Swing. Price, |1.00. 
 
PUBLISHED BY JAN SEN, McCLURG &• CO. 
 MEMORIES : A Story of German Love. 
 
 From the German of Max Muller. Full Gilt. Price,$1.25. 
 
 GRAZIELLA: A Story of Italian Love. From 
 
 the French of Lamartine. Full Gilt. Price, $1.25. 
 
 MARIE : A Story of Russian Love. From 
 
 the Russian of Alex. Pushkin. Full Gilt. Price, $1.85. 
 
 MADELEINE : A Story of French Love. 
 
 From the French of Sandeau. Full Gilt. Price, $1.25. 
 
 FAMILIAR TALKS ON ENGLISH LITERA- 
 TURE. A Manual embracing the GreatEpochB of Englisli Literature, 
 From the English conquest of Britain, 449, to the death of Walter Scott, 
 1832. By Abbt Sage Richardson. Price, $8.00. 
 
 CHOICE READINGS; For Public and Private 
 
 . Entertainments. By Prof. E. L. Cumnock. Price, $1.75. 
 
 SKETCH OF EDWARD COLES, Second 
 Governor of Illinois, and of the Slavery Struirgle 
 of I 823-24. By Hon. E. B. Washbuenb. With Portrait and 
 Fac-simile Letters. Price, $1.50. 
 
 LIFE OF BENEDICT ARNOLD; His Patriot- 
 ism and his Treason. By Hon. Isaac N. Abnold, author of 
 " Life of Abraham Lincoln." Price, $2.50. 
 
 SEWER-GAS AND ITS DANGERS. With an 
 
 Exposition of Common Defects in House Drainage, and Practical Infor- 
 mation relating to their Remedy. By G. P. Bbown. Price, $1.25. 
 
 TALES OF ANCIENT GREECE. By the Rev. Sir 
 
 6. W. Cox, Bart., M.A., Trinity College, Oxford. Price, $1.60. 
 
 SHORT HISTORY OF FRANCE: For Young 
 
 People. By Miss E. S. Kirklanb. Price, $1.50. 
 
 TALES OF .THE CARAVAN, INN AND 
 PALACE. From the German of William Hauff. 
 
 By E. L. Stowell, Illustrated. Price, $1.25. 
 
 Mailed, Prepaid, on receipt of price, iy the publishers, 
 JANSEN, McCLURG & CO., 117 & 119 State St., CHICAGO.