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 UJ^ITED STATES 
 COAST AND GEODETIC SURVEY 
 
 T. C. MENDENHALL 
 
 SUPERINTENDENT 
 
 GEOGRAPHICAL EXPLOaATIONS 
 
 EEPOET OF AN EXPEDITIOIS 
 
 TO 
 
 MUIR GLACIER 
 
 ALASKA 
 
 By HARKY FIELDING- RBID 
 
 I>rofessor of Physics, Case School of Applied Soienoe 
 
 Cleveland., Ohio 
 
 APPENDIX No. 14-REP0R7 FOR 1891 
 
 WASHINGTOIT 
 
 GOVERNMENT PRINTING OFFICE 
 1892 
 
( 
 
UNITED STATES 
 COAST AND GEODETIC SUEVEY 
 
 T. C. MENDENHALL 
 
 SUPEKINTENDENT 
 
 GEOGRAPHICAL EXPLORATIONS 
 
 EEPOET OF AN EXPEDITION 
 
 TO 
 
 MUIR GLACIER 
 ALASKA 
 
 By HARRY If^IELDHSTG- REID 
 
 IProfessor ofPhysics, Case School of A-pplied. Science 
 Cleveland., Ohio 
 
 APPENDIX No. 14-REPORT FOR 1891 
 
 WASHINGTON 
 
 GOVERNMENT PRINTING OFFICE 
 1892 
 

 FEB 13 1905 
 p.ofD, 
 
APPENDIX No. 14.— 1891. 
 
 REPOET OF AN EXPEDITION TO MUIR GLACIER, ALASKA, WITH DETER- 
 MINATIONS OF LATITUDE AND THE MAGNETIC ELEMENTS AT CAMP 
 MUIR, GLACIER BAY. 
 
 By Hakry Fielding Reid, ' 
 
 Professor of Physics at the Case School of Applied Science, CleYeland, Ohio. 
 
 Submitted for publication December 10, 1891. 
 
 INTRODUCTION. 
 
 In tlie spring of 1890 a party was formed, consisting of Messrs. 
 H. P. Ciisliing, H. McBride, E. L. Casement, J. F. Morse, C. A. Adams, 
 and the writer, for the purpose of exploring and studying Muir Glacier, 
 Alaska. All my companions rendered most efficient aid. . Mr. Gushing 
 took entire charge of the geological and meteorological observations. 
 Messrs. Adams and Morse did most of tbe trigonometric work, while 
 the writer did the plane table work, made the magnetic and latitude 
 observations, and had general charge of the expedition. We estab- 
 lished our camp, which we named Camp Muir, near the end of the 
 glacier, on July 1, 1890, and remained there until the middle of Sep- 
 tember, mapping and studying the region. 
 
 Many of the necessary instruments were lent us by the U. S. Coast 
 and Geodetic Survey. A list of them will be given at the end of this 
 report. 
 
 General Geography. — The southeastern extremity of Alaska consists 
 almost entirely of an archipelago of islands, which occupies a space 
 nearly 350 miles long and 100 miles wide. These islands, large and 
 small, are closely packed together, and the waterways between them are 
 deep and narrow, and often form long strait canals. The islands are 
 mountainous and precipitous, affording few landing places. Tlieir slopes 
 are densely wooded, mostly with spruce. The rough surveys of Vancou- 
 ver, a hundred years ago, as revised later by Tebenkof and others, were, 
 until 1867, largely relied upon as supplying the most accurate informa- 
 
 487 
 
488 U. S. COAST AND GEODETIC SURVEY. 
 
 tiou of parts of the coast. Since that year the explorations and surveys 
 made by the U. B. Coast and Geodetic Survey, under the direction of 
 Assistant Davidson, Acting Assistant Dall, and during the period 
 from 1881 to the present time by officers of the Navy attached to the 
 Coast Survey Service, have resulted in the publication of charts and 
 Coast Pilots making known the more important channels and water- 
 ways with ample accuracy for all purposes of navigation. Southeast 
 of the Alaskan boundary the islands become larger and the waterways 
 v/ider. Cross Sound and Icy Strait form the northwestern boundary of 
 the archipelago. Prom them two deep inlets, Linn Canal and Glacier 
 Bay, stretch to the north and northwest, forming, with the Pacific 
 Ocean, two peninsulas. 
 
 Tho great Fairweather group of mountains occupies the western part 
 of the peninsula between Glacier Bay and the Pacific. The eastern 
 part is occupied by another and much lower range, whose peaks rise 
 about 1 800 metres above the sea. Their northeastern slopes are 
 gradual, and are covered with large glaciers, some of which reach tide- 
 water and discharge icebergs into Glacier Bay. Between these two 
 ranges there seems to be a deep valley, which drains the eastern slopes 
 of the Fairweather group. This is probably filled by a long narrow 
 glacier discharging into Taylor or Dundas Bay. 
 
 Little was known of the peninsula between Glacier Bay and Lynn 
 Canal before our expedition mapped its northern part, except that it is 
 entirely made up of glacier-bearing mountains, whose peaks are from 
 
 I 800 to 2 400 metres high. 
 
 Northwest of Cross Sound the character of the coast changes 
 abruptly; the coast line becomes continuous without outlying islands 
 and broken by few inlets. Mountains of great height rise immediately 
 from the water's edge. We can therefore topographically divide the 
 southeast coast of Alaska into two regions; the line between them 
 passes along Cross Sound, then follows the valley just northeast of the 
 Fairweather range for 60 or 80 kilometres, beyond which point we know 
 aothing whatever about it. This topographical difference seems to be 
 accompanied by a geological difference. Mr. Eussell has shown that 
 the St. Elias Alps are of tertiary origin, and probably the Fairweather 
 group belongs to the same range, though I believe it has not been at 
 all explored. If this is true, the Fairweather Mountains are of tertiary 
 origin, while the mountains about Muir Glacier, and probably the rest 
 of the same topographical region to the southeast, belong to paleozic 
 and archean time. {See Nat. Geog. Magaz., Vol. iv, Supplements i and 
 
 II to "Studies of Muir Glacier".) 
 
 Another difference is quite marked. Mr. Eussell has found raised 
 beaches about Yakutat Bay, indicating that the land there has risen, 
 whereas the submerged trees in Muir Inlet show that this region is 
 sinking. These striking facts seem to show that the valley between 
 the Fairweather Mountains and Glacier Bay follows the line of an 
 
REPORT FOR 1891 PART II. 489 
 
 Report of an Expedition to Muir Glacier, Alaska, etc. — Coutimud. 
 
 immense geological fault, which brings tertiary and paleozoic rocks 
 into close juxtaposition. It is most unfortunate that we have no obser- 
 vations on the Fairweather Mountains that will enable us to confirm or 
 correct this interesting indication. 
 
 Glacier Bay and Muir Inlet. — G-lacier Bay itself has not been sur- 
 veyed; its delineation in the Coast Survey charts is correct only in its 
 general outline. It lies northwest and southeast and is about 65 kilo- 
 metres long by 15 kilometres wide. There are a great many islands in 
 the bay. The Beardslee Islands, which fill the eastern side for a dis- 
 tance of about 30 kilometres from its mouth, are made up, at any rate, 
 in part, of modified glacial till, and are generally thickly wooded, as 
 are also the shores in the lower part of the bay. The channels betweeen 
 these islands are narrow, and often give one the impression of water- 
 ways cut through the land. The islands in the upper part of the bay 
 are quite different; they are of solid rock, and are scored, polished, and 
 rounded by glacial action ; they occur singly, are usually elongated, and 
 have the long axis parallel to the nearest shore. They, like the main 
 land, descend abruptly into the water, and only at long intervals can 
 even a small beach be found. In this part there are no trees. Several 
 glaciers force their way down to the water's level and discharge bergs 
 into the bay; most of them end in a narrow inlet two or three miles back 
 from the bay proper. Muir Glacier is of this type ; its inlet, which runs 
 about north and south, has its southwestern terminus on G-lacier Bay 
 about 8 kilometres from the end of the glacier ; the eastern shoreline 
 rounds gradually into the bay without any well-marked headland. 
 The inlet gradually narrows as we approach the glacier, being about 
 2-5 kilometres wide at its upper end. On each side are deposits of 
 roughly stratified sands and gravels, covered with a thin layer of mo- 
 raine debris. On the west side, these deposits form a comparatively 
 level plateau from 45 to 60 metres high, which extends about 6*5 kilo- 
 metres south of the present ending of the glacier, and is about 1-6 kilo- 
 metres wide. Its surface bears a number of shallow lakes; and here 
 and there deep ravines mark the position of former water courses- 
 The western subglacial stream has cut a gorge through this plateau, 
 and exposed the buried forest described by Prof. Wright.* For three- 
 quarters of its length the plateau ends on the water side in precipitous 
 bluffs, below which there is a narrow beach, only covered by the high- 
 est tides. On the east side the bluffs only extend for a kilometre or 
 so; the upper surface of the deposit is not a plateau, but slopes gradu- 
 ally down to the bed of the glacial stream at the foot of the mountains. 
 This stream empties into the inlet just below where the bluffs end. 
 South of the stream the deposits slope gradually up from the beach to 
 a height of about 120 metres against the mountain side. 
 
 * Ice Age ill North America, cli. HI. 
 
490 U. S. COAST AND GEODETIC SURVEY. 
 
 The inlet is quite deep. Prof. Wright reports a sounding by Capt. 
 Hunter of 86 fathoms about 1 200 metres south of the present position 
 of the ice-front. Capt. Carroll last summer (1890) found within 100 
 metres of the ice-front a dei)th of 120 fathoms. This does not necessa- 
 rily indicate that the inlet increases in depth as we approach the imme- 
 diate neighborhood of the ice, for the earher sounding may not have 
 been taken in the deepest part of the channel. 
 
 3fuir Glacier. — Muir G-lacier (see illustration !N"o. 22) occupies a de- 
 pression in the mountains about 60 kilometres long and from 10 to 15 
 wide. It is fed by a great number of tributaries, of which the First 
 ISTorthern, the Second Northern, and the Northwestern are by far the 
 largest. These again are made uj) of many smaller glaciers. The gen- 
 eral slope of the surface is about a degree and a quarter. This is based 
 on a barometrical reading made between Tree Mountain and Granite 
 Canon. The appearance of the glacier to the northwest indicates that 
 the slope there is about the same. The total area drained by this sys- 
 tem is about 2 250 square kilometres, the actual surface of the ice being 
 about 1 000 square kilometres. The area draining into Muir Inlet is 
 about 2 000 square kilometres. Most of the precipitation which falls 
 on this area flows off as water in the subglacial streams j the rest, com- 
 pressed into ice, is forced through the narrow gateway about 4 kilome- 
 tres wide into the inlet, where the glacier terminates in a vertical wall 
 of ice, varying from 40 to 65 metres above the water's surface, from 
 which large masses are continually separating to become icebergs. As 
 already said, the depth of the water is in places 120 fathoms or 220 
 metres, and as this is not enough to float a mass of ice which rises 
 as high above the water as Muir G-lacier does, the ice must reach to the 
 very bottom, and must attain a thickness of 275 metres. The actual 
 length of the ice-front facing the water is 2 800 metres. On each side 
 the glacier sends forward a wing, which rises in the shape of a wedge 
 over the stratified sands and gravels of the shore. The upper surfaces 
 of the wings, like the ice-front, are about 60 metres above the water 
 level. This applies only to the parts of the wings overlooking the inlet ; 
 the parts nearer the side mountains are 15 to 30 metres lower, and here 
 the ice ends like an ordinary ali^ine glacier. The wings are fringed 
 by treacherous quicksands, which support large stones and look firm 
 enough, but the tourist who steps uj)on them carelessly will quickly 
 sink in over his ankles. These quicksands are composed of fine glacial 
 mud, thoroughly soaked with water from the melting ice. 
 
 The ice-front has a wonderful coloring. Places from which ice has 
 recently broken off are deep blue, sometimes almost black. This color 
 lightens under exposure to the air and sun, and in a few days becomes 
 pure white. All stages are represented in the ice-front, which there- 
 fore shows aU shades of blue in striking variety. 
 

Digitized by the Internet Archive 
 in 2011 with funding from 
 The Library of Congress 
 
 http://www.archive.org/details/reportofexpeditiOOreid 
 
Ciigx/ and Gvodftie SiiJ~i ey Report ICSl Part //" 
 
REPORT FOR 1891 PART 11. 491 
 
 Report of an Expedition to Muir Glacier, Alaska, etc. — Continued. 
 
 Tributaries. — Beginning at the right (see the illustration), we find 
 three tributaries coming in from the southeast. The Dirt Glacier 
 sweeps around in a great curve from behind Mount Wright; its lower 
 part is completely covered with debris for fully 2-5 kilometres from its 
 mouth; above this the glacier is particularly clean. The White 
 Glacier, which joins the Muir just beyond Mount Case, is remarkably 
 beautiful. Arising in a circle of snowy mountains, it flows down a 
 deep and narrow valley at an angle of about 10°, its very white surface 
 marked by the wonderfully symmetrical parallel curves of three or four 
 dark moraines. It is about 6-5 kilometres long and 0*8 wide. A little 
 farther is the Southeastern Tributary, fed by a number of smaller 
 glaciers. This glacier is not hemmed in by mountains, but crosses a 
 divide to the east of «a5, over which the ice flows into some valley on 
 the other side. This divide has an altitude of 600 or 750 metres. 
 About 15 kilometres southeast of our camp a large glacial stream dis- 
 charges into Glacier Bay. It must drain the southern side of the 
 mountains which bound these three tributaries. 'A little farther to the 
 east is Main Valley, which, though it probably once contained a. tribu- 
 tary, is now an outlet of Muir Glacier. The ice flows down this valley 
 in a stream 3 miles wide, but ai^parently with a very slow motion. A 
 few miles down the valley the ice ends in a high wall facing Main 
 Lake, into which it occasionally discharges a berg. The stream drain- 
 ing this lake flows through a broad flat valley of sands and gravels to 
 the southeast, and finally empties into Lynn Canal. The three valleys 
 entering the eastern side of Main Valley also have flat, gravel-covered 
 floors, thi^ough which rush the streams from the snow fields and small 
 glaciers at their heads. Two of these valleys are beyond the present 
 termination of the glacier. Formerly the ice must have extended 
 across their mouths, hemming them in and converting them into lake 
 beds. The upper valley is now in just this condition. The lake which 
 occupies it has been called Berg Lake on account of the great number 
 of icebergs in it last summer (1890). Just to the north of the entrance 
 to Main Valley lies the Girdled Glacier, so called on account of the 
 moraine which completely surrounds it; it can be seen from the end of 
 Muir Glacier, but is so fore-shortened that one would not suspect that 
 the visible portion is 5-5 kilometres long. To the west and separated 
 from the Girdled Glacier only by a narrow ridge is Granite Canon, a 
 deep gorge with precipitous sides running about 13 kilometres into the 
 heart of the mountains.* The ice slopes downward into the caSoii, 
 whose drainage, however, must be back under the ice; for although I 
 was unable to see every point of the ridge which closes in the back of 
 this valley, I could see sufficient of it from different points of observa- 
 tion to convince me that no part of it was less than 300 metres above 
 
 "This was named from the crystalline nature of tLe rock, which, however, is not 
 a true granite. (See paragraphs under heading Geology.) 
 
492 U. S. COAST AND GEODETIC SURVEY. 
 
 the floor of tlie valley. This curious couditiou seems to be due to the 
 fact that this valley once contained a tributary glacier, which on 
 account of the present smaller supply of ice, and the reflection of the 
 heat from the northern side of the canon, has melted down more 
 rapidly than the surface of the main glacier; so that now, although this 
 I could not see, the glaciers draining into this valley are probably 
 entirely separated from the ice entering at its mouth. The tributaries 
 so far mentioned supply none of the ice which forms ice front in Muir 
 Inlet; all the ice coming from them that does reach the end of the 
 glacier is compressed into about 750 metres between the ice front and 
 the mountain to the east. If a line were drawn from station H to the 
 eastern side of the first Northern Tributary, and a second line to the 
 northwest at right-angles to the first, the sources of all the ice which 
 reaches the ice front would lie in the quadrant between them. 
 
 The first and second Northern Tributaries, and the main glacier 
 present no striking peculiarities. These are immense streams of ice 
 fed by innumerable smaller glaciers; the mountains which rise 
 between them and through them are deeply laden with snow, and 
 toward the northwest seem to raise only their summits through the 
 icy sea. The extremities of these branches could not be clearly de- 
 termined, although they all seem to connect by low divides with valleys 
 beyond. The Northwestern Tributary heads in two beautiful white 
 conical-looking mountains, which we have called the Snow Cones. A 
 part of its ice flows over the divide between I3 and I5 and joins a large 
 glacier which is probably identical with the one which enters the head 
 of Glacier Bay. The Western Tributary supplies no ice to the ice front; 
 moreover, its snow fields are too small and too low to supply ice for a 
 glacier of its width, and it is evidently melting away. At its western 
 extremity it crosses over a divide and flows into a valley beyond. 
 
 The mountains immediately surrounding Muir Glacier are not high, 
 the highest peaks being between 1 800 and* 2 400 metres. The moun- 
 tains which first attract the attention of the visitor are Mount 
 Wright,* Mount Case,t and Pyramid Peak; the first two, by their 
 jagged crests, seamed by snow couloirs; the last by its symmetrical 
 form; all three by their proximity. The more distant mountains seem 
 to lack somewhat in individuality; this is largely due to their distance, 
 for they are from 25 to 50 kilometres away. AU is bare and bleak, and 
 the scenery is entirely lacking in picturesqueness. If we go out on 
 the ice as far as H the three bold peaks of Mount Young show them- 
 selves over Tree Mountain; and the beautiful Snow Cones at the 
 head of the Northwestern Tributary can be seen. 
 
 Drainage. — The principal drainage of the glacier is into Muir Inlet. 
 On each side of the inlet a large stream issues from the end of the ice 
 
 * Named after Prof. Wright, who spent some time studying Muir Glacier in 1888. 
 He has described it in his Ice Age in North America. 
 
 t After the Case School of Applied Science, Cleveland, Ohio, 
 
REPORT FOR 1891 PART II. 493 
 
 Report of Ml Expedition to Muir Glacier, AlasJca, etc. — Continued. 
 
 at a number of points, and after a rapid course of between 1-5 and 2-5 
 kilometres empties into the inlet, forming quite a large delta. T^hese 
 streams were about 10 metres wide and half a metre deep. Their 
 course is so swift that they roll down stones as large as one's fist; but 
 the principal material that they carry off is in the form of fine mud. We 
 used this water largely in our camp, and found that although most of the 
 mud would precipitate when allowed to stand for a few hours, still the 
 water remained quite turbid even after three or four days. The muddy 
 character of the water in the inlet a little west of the middle of the ice 
 front shows that another stream must discharge iu that region, either 
 under or through the ice. A small part of the drainage of the glacier 
 passes down Main Valley, but this does not amount to very much. I 
 think the principal sources of the stream in this valley are from the 
 snow^ fields and smaller glaciers on its sides. 
 
 Geology. — The geological observations were undertaken by Mr. Cush- 
 ing. Some rocks collected near the glacier were submitted for micro- 
 scox)ical examination to Dr. George H. Williams, of the Johns Hopkins 
 University. The following is extracted from their reports.* The rock 
 bordering the glacier on the south and southeast is slate. It has a 
 very variable," but in general, high dip to the southwest, and is much 
 faulted. On the east side of Muir Inlet this is overlaid conformably by 
 limestone, the junction reaching tide water, about 13 kilometres south- 
 east of the glacier. The southwestern shore of Glacier Bay and the 
 islands near it are composed of this rock. In one of these islands Mr. 
 Gushing found fossils which make it probable that the limestone and 
 underlying slate are of paleozoic age. 
 
 The western part of the glacier's basin consists of quartz diorite, 
 light gray in color. The line of junction with the slates, beginning at 
 the small glacier on the northern shoulder of Pyramid Peak, runs 
 easterly, passes between the F and K ridges, and then between H and 
 I. It then turns to the northwest, passing between ^5 and fl. The 
 northern mountains are diorite, bordered on the south by a narrow 
 band of slate. The eruptive rocks (the diorites and quartz diorites) 
 are full ot dikes running iu all directions. The eruptions occurred at 
 two or more periods. Some of these rocks are very old, and closely 
 resemble archean terranes occurring in the Cordilleras further south. 
 Although the c'iificulties of travel prevented Mr. Gushing from exam- 
 ining the region very thoroughly, he thinks we have to do here with a 
 tilted block dipping towards the southwest, but much distorted by 
 minor folds and by faults. 
 
 Changes going on. — Many indications show that Muir Glacier is 
 becoming smaller, and considerable changes may be expected before 
 many years. Main Lake and Berg Lake are now separated by a very 
 
 * These reports are given in full in "Studies of Muir Glacier," Nat. Geog. Mag., 
 Vol. IV. 
 
494 U. S. COAST AND GEODETIC SURVEY. 
 
 short distance, and it will not be long before they nnite. This will 
 result in the draining of Berg Lake, which event will probably be 
 marked by a flood. The melting of the ice in Main Valley must be 
 rapid, for .the great extent of its termination there presents a large 
 surface for melting. When this termination has receded 4 or 5 kilo- 
 metres, and the surface of the ice has sunk 60 to 100 metres, the ice 
 from the first northern and from the southeastern tributaries will 
 probably be in part deflected into Main Valley. 
 
 The small lake which occupies a lateral valley opening into Granite 
 Canon will probably extend as the ice diminishes, and perhaps occupy 
 a large part of the canon itself. 
 
 Prof. Wright has kindly sent me some photographs which he 
 took of the glacier in 1880. By comparing these with our ^photographs 
 'we can readily fix on our map, within 100 metres, the position of the 
 ice front at the time of Prof. Wright's visit. This shows that in 
 the four years from 1886 to 1890, the western end of the ice front has 
 receded 1 100 metres and the eastern end 900 metres. The center has 
 also receded about 1 100 metres, so that the average recession of the 
 ice front is about 1 000 metres in four years. Prof. Muir writes 
 me that the notes of his first visit to the gla-cier in 1879 show that the 
 ice then extended almost to our station D. The rate of retreat deduced 
 from this accords fairly well with that given above. The ice front, 
 therefore, must have extended as far as island C twenty years ago. 
 Below C, I think the retreat was more rapid, for there the glacier 
 presented a much wider front to the water, from which a correspond- 
 ingly larger quantity of ice must have broken off. And this could 
 hardly have been entirely comx^ensated for by a greater velocity of 
 flow, on account of the many obstructions in the neighborhood of the 
 present position of the ice front. It does not seem at all incredible 
 that the ice from the various glaciers of Glacier Bay may have united 
 to fill a large ijart of the bay a hundred years ago. Prof. Wright's 
 interpretation of Vancouver's description seems perfectly in accord 
 with what our observations would lead us to conclude. 
 
 The retreat is probably not regular, but is faster some years than 
 others; and even varies considerably at difterent parts of the same 
 season. For two or three weeks in August (1890) there was scarcely 
 any fall of ice; in the two weeks following the fall was so rapid that a 
 great bay, fully a quarter of a mile deep, was made in the eastern part 
 of the ice front, which was, before this, only slightly concave. I have 
 collected on the uiap the positions of the ice front at several periods ; 
 this shows the retreat at a glance, much better than it can be described 
 in words. The changes in the shape of the front will also be evident. 
 
 The present rate of recession of the ice front in Muir Inlet, a kilo- 
 metre in four years, will probably be exceeded in the near future, for 
 it has reached a point where the conditions change. The deposits 
 which support the wings are almost at the water's level at the ice 
 
REPORT FOR 1891 PART IT. 495 
 
 Report of an Expedition to Muir Glacier, Alaska, etc. — Continued. 
 
 front, and slope down at an angle of 6° or 7°; a little further back 
 tliey will be below the water's level and the ice front will be broader, 
 resulting in an increased amount of loss by breakage, and hence a more 
 rapid retreat. Ten or fifteen years will probably see the Dirt Glacier 
 on the east and the Western Tributary on the west, entirely separate 
 from the main- ice stream. The middle part of the valley which con- 
 nects Muir Inlet with the upper jjart of Glacier Bay is now occupied 
 by a small glacier without feeders, evidently the remains of a much 
 larger body of ice. It probably derived its supply principally from 
 the main body of ice which formerly tilled the bay. This glacier, which 
 we called the Dying Glacier, is rapidly melting away; in fifteen or 
 twenty years I think its bed will be emx)ty. The maps I have made 
 will enable us to determine with considerable accuracy the amount of 
 these changes in the future. I should, however, say that although the 
 northern end of Main Lake is in its right i)lace, the southern end is 
 only approximately determined. The ends of the Dying Glacier are 
 also only approximate. 
 
 THE SURVEY. 
 
 I. — BY TRANSIT. 
 
 The west side of the inlet was the best place for measuring our base 
 line, as it offered a pretty long stretch of fairly level ground. The 
 base line was measured on July o, with a 30-metre steel tape (Ko. 23 
 U. S. Coast and Geodetic Survey). 
 
 Wooden stakes were driven into the ground, and into the top of each 
 was driven a tack; the measures were all made from the north edges 
 of the tacks. The tape was stretched by a spring until the tension was 
 16 pounds. Where the ground sloped, the tape' was held as nearly 
 level as x^ossible, and i)lumb bobs were used to project the tape upon 
 the edge of the tack. The base was measured twice, first from B to A, 
 and then from A to B. The two values obtained were 962*301 and 
 962*330 metres. This close agreement shows that the measures were 
 carefully made; and the average adopted, 962*32 metres, is probably 
 not in error by 5 centimetres. The temperature of the air was 12-5o C, 
 and would cause but a slight correction if the tape, as usually made, 
 were correct at ordinary temperatures. No temperature correction 
 was introduced. White flags were planted at the ends of the base line 
 and the stations called B (north end) and A (south end). The stations 
 A and B were then determined trigonometrically. Angles were taken 
 from these stations and from D, Camj), E, and K. The transits used 
 were Casella 120 and 3123, having 2^-inch horizontal and vertical 
 circles reading to minutes by two verniers, and telescopes magnifying 
 5|^ times. The angles were measured several times; the sum of the 
 three angles of the various triangles differed on an average about 2' 
 from 180°. The excess or defect was divided between the three angles, 
 
496 U. S. COAST AiS^D GEODETIC SURVEY. 
 
 but no attemj)! was made to make the sum of tlie angles at a particular 
 station equal to 360°. The points L, M, &4, Ca, were also determined 
 trigonometrical] y. but the transit was not set uj) at those points. The 
 following- are some of the distances thus determined (A — B is the base 
 line measured) : 
 
 Metres. Metres. 
 
 A — B 962-32 D — M 1075-6 
 
 E--D 2492-2 E— M 1973-2 
 
 DCamp 819-26 M — L 2444-7 
 
 E Camp 2201-2 E — /54 23713 
 
 D — L 3091-0 E — C2 28865 
 E — L 41 10-2 
 
 The distance D — E was determined through the four triangles B, D, 
 B; K, B, E5 Camp, D, E; and A — B, D, E; the other two sides of 
 each of these triangles having been already determined. The average 
 gives 2492*2 as in the table, which is probably true to the fourth figure. 
 At E and at D cairns of stones were made surrounding the flag. These 
 cairns were about four feet high, and were made of the largest stones 
 that we could move, so piled u}) as to hold the flags firmly in their 
 midst. I think they will remain if unmolested five or ten years, and 
 will serve to connect our map with any future surveys that may be 
 made in this region. If these cairns should not last t think the two 
 peaks. Mount Wright and c4, would make the best points of connection. 
 The former on the east side of Muir Inlet can not be mistaken j the 
 latter is a sharp peak with symmetrical shoulders, and when seen from 
 the end of the glacier is slightly to the west of the entrance of Granite 
 Caiion. It is the highest peak in its neighborhood. 
 
 The meridian line was determined near our camp in connection with 
 observations for magnetic declination, but it was not determined at any 
 of our trigonometric stations, and therefore we must determine the 
 orientation of our map graphically. This gives for the direction of 
 the line E — D, N. 41° 43' E. (astron). The error is probably not more 
 than 5'. 
 
 Altitudes were determined trigonometrically with respect to Camp 
 Muir, and 8 metres (the estimated height of the latter above mean tide) 
 added. The following are some of these altitudes : 
 
 
 A/etres. 
 
 
 Metres. 
 
 Camp Muir, 
 
 ' 8 
 
 Mount Case, 
 
 1679 
 
 E, 
 
 271 
 
 Wright, 
 
 1507 
 
 D, 
 
 32-5 
 
 H> 
 
 1678 
 
 A, 
 
 53 
 
 C2, 
 
 1995 
 
 B, 
 
 59 
 
 d2, 
 
 2 175 
 
 Pyramid Peak, 
 
 I 240 
 
 d\. 
 
 1473 
 
 We expected to determine many altitudes by simultaneous observa- 
 tions of the barometer at camp (mercurial barometer 1738, Coast and 
 (jreodetic Survey) and of the aneroids at other points. But the latter 
 instruments worked so unsatisfactorily that few of our barometrical 
 altitudes were reliable. Only the reliable ones have been entered on 
 the map. 
 
REPORT FOR 1891 PART II. 
 
 497 
 
 Report of an Uxpedition to Muir Glacier, Alaslca, etc. — Continued. 
 
 II. — BY PLANE TABLE. 
 
 The instriiment used was Plane Table I^o. 81 of the U. S. Coast and 
 Geodetic Survey. The table itself was 39 by 49 centimetres. The top, 
 alidade, and trii)od complete weighed about 40 pounds, and was very 
 clumsy to carry. 
 
 The scale of the map was 1-99300. This was changed to 1-100000 
 for the final map. I have carefully abstained from filling in uncertain - 
 portions of the map conjecturally; I have, however, in some places 
 added with dotted lines the ridges or peaks whose iDositions were 
 roughly determined, also the boundaries of some small tributary gla- 
 ciers, when the positions of the surrounding ridges made it probable 
 that no serious error could be made. Contour lines of 200 feet were 
 added on the glacier to show the general shape of its surface, but they 
 pretend to no accuracy. 
 
 The survey was begun at E and H. The point H, though not de- 
 termined trigonometrically, had its position fixed as soon as some trigo- 
 nometric stations were plotted in. The i)lane table was also set uj) at 
 Camp, D, L, M , O, P, E, IS", S, T, and V j the j)ositions of all these sta- 
 tions except the first four being determined by the three-point method, 
 by aid of mountain peaks, which had already been plotted in. The 
 points determined by plane table or trigonometrically are marked thus: 
 © , on the map. I do not think any of these points are out of their true 
 position by 1% of their distance from E. At each of the stations V, 
 O, P, E, ]Sr, and T, a number of photographs were taken in different 
 directions. These have been very useful in working up details of topog- 
 raphy, and in some instances have served to fix with considerable accu- 
 racy the position of certain i)eaks and thus the direction of some ridges. 
 I have also made a map* of the northern part of the Muir Inlet on a 
 scale of 1-20000. This map shows pretty well the general topography of 
 this region, and also the jiosition of the ice-front at various dates. It also 
 shows where we planted our flags for measuring the motion of the ice. 
 This work was carried out with great care. The greatest velocity we 
 found was 2.2 metres a day for Flag 6^ The side flags showed scarcely 
 any motion. 
 
 Geographical position. — The latitude of our camp was determined by 
 the following observations on the meridian altitude of the sun, made 
 with the Casella 2|-inch transit No. 120: 
 
 Date. 
 
 Station. 
 
 Latitude of 
 station. 
 
 Latitude of 
 Camp Muir. 
 
 1890. 
 July 13 
 16 
 
 17 
 
 Sept. 8 
 
 Camp Muir, 
 E, 
 K, 
 
 Camp Muir, 
 
 / 
 
 58 4975 
 58 5025 
 58 50-50 
 58 50 
 
 / 
 
 58 4975 
 58 49-75 
 58 49-50 
 58 50 
 
 * See Nat; Geographic Magazine, Vol. iv, Plate 15. 
 H. Ex. 43, pt. 2—32 
 
498 us. COAST AND GEODETIC SUEVEY. 
 
 This gives an average of 58° 49'.7 for Camp Muir. Our instruments 
 read to minutes, so that this average can not be relied on closer than a 
 half minute, though I do not think the error is greater than this. This 
 would make the latitude of E 58° 50'.5. 
 
 IsTo satisfactory determination of longitude was made. When we first 
 went into camp the chronometer was unfortunately allowed to run 
 down; and when we left, it stopped without any apparent reason. An 
 attempt was made to determine longitude by comparing our chronome- 
 ter with those of the steamers of the Pacific Coast Steamship Company, 
 which brought tourists every week to see the glacier; but these chro- 
 nometers differed so much among themselves that no reliance could be 
 put on the result. 
 
 Mr. Junken, of the Coast Survey, by reference to the best map of the 
 region, which is somewhat conjectural, has given me as the longitude 
 of our camp 136° 8' west of Greenwich, which he thinks is not in error 
 more than 5'. I have adopted 136° 5' west. 
 
 The eastern limit of the region surveyed must lie between 12 and 20 
 kilometres from the shore of Lynn Canal, and probably the mountains 
 on the east of our map are visible from Sullivan Island. Davidson Gla- 
 cier must have tributaries in the mountains which close up Granite 
 Carion. Whether or not one of its tributaries connects by a compara- 
 tively low divide with the First Northern Tributary of Muir I can not 
 say ; but it does not seem impossible. If there is any such connection 
 between these two glaciers, the point indicated is where it wiU undoubt- 
 edly be found. 
 
 Magnetic observations. — These were made with the Bache Fund 
 Magnetometer and Dip Circle Xo. 12 (of about 24 centimetres diam- 
 eter), both belonging to the Coast and Geodetic Survey. The magnetom- 
 eter was not adapted for determining deflections, but only for declina- 
 tions and oscillations. For the latter a mean time chronometer (No. 
 1285, Coast and Geodetic Survey), was used. The moment of inertia was 
 determined in the field. For this purpose a special stirrup was made. 
 The upper bar of the stirrup was cylindrical, 2 millimetres in diameter, 
 and carried two small brass cylinders, which could slide on it so as to 
 press against stops near the center of the bar (cylinders "in"), or 
 against stops at the ends of the bar (cylinders "out"). The moment 
 of inertia of the system could thus be altered by a definite amount (the 
 increase was about four-fifths of the moment of inertia with cylinders 
 "in") without changing the mass. The masses and distances between 
 the centers of mass of the cylinders, "in" and "out," were determined 
 in the laboratory before starting on the expedition. 
 
 The variation of magnetic moment with temperature was determined. 
 Two series of observations gave, respectively, for the coefficient of 
 variation for 1° centigrade, -00073 and '00077. The mean was 
 adox)ted. The magnetic moment of the magnet was determined some 
 time after our return; and I do not think the values of the horizontal 
 and total forces can be relied on more closely than 1 or 2 per cent. 
 
REPOET FOR 1891 PART II. 
 
 499 
 
 Eeport of an Expedition to Muir Glacier^ AlasJca, etc. — Continued. 
 
 Quantities given in this report are in Coast and Geodetic Survey 
 units (C. G. S). In the observations for declination, tlie astronomical 
 meridian was determined by afternoon observations on the sun. 
 
 Special tents were erected for the magnetic instruments at Camp 
 Muir. The magnetometer was 80 and the dip circle 60 metres from our 
 tents. During the observation with the former the latter was about 
 100 metres distant. 
 
 Magnetic observations at Camp Muir, Glacier Bay, Alaslca. 
 
 Date. 
 
 Declination.* 
 
 Daily approxi- 
 
 Dip. 
 
 Horizontal in- 
 
 Total in- 
 
 
 
 mate range., 
 
 teiisity. 
 
 tensity. 
 
 1890. 
 
 / 
 
 / 
 
 / 
 
 
 
 Aug. 22 
 
 
 
 
 •150 
 
 
 23 
 
 
 
 75 49-8 
 
 
 Sept. 5 
 
 
 
 75 517 
 
 
 
 8 
 
 — 30 27-8 
 
 6-9 
 
 
 
 
 9 
 
 — 30 26-1 
 
 8-4 
 
 
 
 
 10 
 
 — 30 24-1 
 
 5-4 
 
 
 
 
 Mean, 
 
 — 30 26 
 
 6-9 
 
 75 50-8 
 
 0-150 
 
 0-614 
 
 * The negative sign means easterly declination. The observations were made by the writer. 
 
 Meteorological.—RegulaT observations were made under the direction 
 of Mr. Cushing, and a complete record sent to the U. S. Signal Service. 
 The barometer used was No. 1738 of the Coast and Geodetic Survey. 
 The maximum, minimum, wet, and dry bulb thermometers were lent me 
 by Prof. Whitman, of Adelbert College, The rain gauge was lent by 
 the Signal Service. 
 
 A short summary of these observations is appended.* 
 
 1890. 
 
 Temperature. 
 (Fahrenheit scale.) 
 
 Barometer. 
 (Inches.) 
 
 Rain- 
 fall. 
 
 Mean 
 humidity. 
 
 Mean. 
 
 Max. 
 
 Min. 
 
 Mean. 
 
 Max. 
 
 Min, 
 
 July. 
 Aug. 
 
 
 45-2 
 45-1 
 
 
 63-1 
 63-9 
 
 
 
 '35-4 
 27-2 
 
 30-089 
 30-123 
 
 30-335 
 30-418 
 
 29-565 
 29-787 
 
 3*06 
 4-88 
 
 82-2 
 83 
 
 LIST OF INSTRUMENTS LENT BY THE U. S. COAST AND GEODETIC 
 
 SVRVEY. 
 
 Two CaseUa Theodolites (Nos. 120 and 3123). 
 
 Two Telemeters (No. 81). 
 
 One 20-metre Steel Tape (No. 23). 
 
 One Plane Table (No. 81). 
 
 * For an aocount of other observations made on this expedition see Studies of Muir 
 Glacier in the Nat. Geog. Mag., Vol. iv. 
 
500 U. S. COAST AND GEODETIC SURVEY. 
 
 One Bache Fund Magnetometer. 
 
 One Mean Time Chronometer (E"o. 1285). 
 
 One Dip Circle (No. 12). 
 
 One Artificial Horizon (No. 30). 
 
 One Mercurial Barometer (IsTo. 1738). 
 
 One Prismatic Compass (Ko. 108). 
 
 Two Draw Telescopes (Nos. 114 and 116). 
 
 One Clinometer (IS^o. 3). 
 
 Two IS^egretti & Zambra Deep-Sea Thermometers (Nos. 66727 
 and 57080). 
 
 Two Casella Aneroid Barometers (Nos. 1098 and 2738). 
 The telemeters, artificial horizon, and deep-sea thermometers were 
 not used. 
 
 In addition to these a transit and several other instruments belonging 
 to the Case School of Applied Science, and a number of thermometers, 
 aneroids^ compasses, etc., belonging to various members of the 
 expedition, were taken with us. 
 
 MAGNETIC OBSERVATIONS AT CLEVELAND, OHIO, 1891. 
 
 The following observations of the magnetic elements were made at 
 Cleveland on April 6 and 26, May 30 and 31, and June 1, 1891. The 
 station was the pier in the grounds of the City Hospital, which forms 
 the north end of the meridian line laid down by the U. S. Coast and 
 Geodetic Survey. This is the station occupied by the Coast Survey 
 party in 1871 and 1880. It is not far irom the hospital building and 
 within 200 yards of the railroad. A passing train did not seem to 
 deflect the needle more than a minute of arc. 
 
 The instruments used were Dip Circle li^o. 12, and the Bache Fund 
 Magnetometer, both belonging to the Coast and Geodetic Survey. A 
 small tent was erected to protect the instruments from the wind and 
 rain. 
 
 The magnetic moment of the magnet was determined at the Case 
 School of Applied Science April 6 and on May 26. The needle was 
 oscillated again at the same point on June 9, and the product mH (from 
 the two sets of observations) differed about 1 per cent. This is within 
 the limit of errors of observations. The stirrup supporting the magnet 
 with the two movable cylinders was the same that was used in the 
 observations at Camp Muir, Alaska, in the summer of 1890. 
 
 The dip was determined on May 31, and June 1, the values obtained 
 being 72° 34' and 72° 44' respectively; mean 72° 39'. This is less than 
 the former values (1880) obtained here by nearly half a degree, but 
 only 11' less when compared with the observations of 1888 as deter- 
 mined by the U. S. Coast and Geodetic Survey. The secular change is 
 diminishing the dip. 
 
REPORT FOR 1891 — PART II. 
 
 501 
 
 Report of an JEJxpedition to Muir Glacier, AlasJca, etc. — Continued. 
 
 The meridian lire laid down by the Coast and Geodetic Survey was 
 used, and no astronomical observations were made for declination 
 determinations. These were obtained from maximum and minimum 
 elongations. ' 
 
 Declination ohtained. 
 
 Date. 
 
 Mean 
 declination. 
 
 Apparent 
 daily range. 
 
 1891 
 May 30 
 May 31 
 June I 
 
 Mean 
 
 / 
 2 18-4 W 
 2 i8'3 W 
 2 19-0 W 
 
 16 
 10 
 
 9 
 
 2 19 w 
 
 12 
 
 This declination is about one-third of a degree greater than predicted 
 in Appendix 7, U. S. Coast and Geodetic Survey Eeport for 1888, p. 
 264, but only 12' greater than the revised expression* for the secular 
 variation sent me from the Survey Office, and which includes my 
 observation. 
 
 The horizontal intensity was found from observations on April 6 and 
 26 to be -1833 and -1825, average 0-183, which is ijrobably not in error 
 more than 1 or 2 per cent. The total intensity is 0*614 of a dyne. 
 
 The nearness of the hospital, the iron railings around the grounds, 
 and the railroad, now make this station an undesirable one for mag- 
 netic observations. 
 
 •^D = -{- 0*77 -|- 2*53 sin. (1"3 m — 21'6), where m=year of observation — 1850. 
 
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