ANTARCTICA SECTION 22 OCEANOGRAPHY AND COASTS

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CIA-RDP97-00952R000200250001-2
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RIPPUB
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C
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133
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December 27, 2016
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December 18, 2013
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1
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Publication Date: 
December 2, 1957
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REPORT
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Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL CHAPTER II NATIONAL INTELLIGENCE SURVEY ANTARCTICA SECTION 22 OCEANOGRAPHY AND COASTS CENTRAL INTELLIGENCE AGENCY Washington, D. C. NIS 69 4 Ics 3.) 50X1 IICONFIDENTIAL, Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 , WARNING This document contains information affecting the national defense of the United States, within the meaning of Title 18, Sections 793 and 794, of the U. S. Code, as amended. Its transmission or revelation of its contents to or receipt by an unauthorized person is prohibited by law. GPO-DSSO--5579 i?m, Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part- Sanitized Copy Approved for Release @50-Yr 2013/12/18: et No. 17 CIA-RDP97-00952R000200250001-2 Date) 2 December 1957 MEMORANDUM FOR: All Recipients of NIS Publications SUBJECT: Corrections to NIS 69 (Antarctica) Section 22 (Coasts and Landing Beaches) 1. All recipients of the NIS are requested to make the following changes in NIS 69 (Antarctica) Section 22 (Coasts and Landing Beaches), dated January 1956: Page 22-13, left column Line 20 from bottom, for "about 90%" read "about 70% to 80%" Line 19 from bottom, for "between 55? and 60?S." read "at about 550S." Line 14 from bottom, for "and at 50?S." read "and more than 60% of the time at 50?S." Page 22-13, right column Lines 12 through 15 from top, delete "A belt" through "is intended" and substitute:_ "The belt of maximum occurrence of rough-to-high seas appears to have moved northward during this season. In general, isolines to the south of this area have been drawn to conform to this pattern." Line 17 from bottom, for "is" read "continues" Line 16 from bottom, for "of the Area" read "in winter" and delete "or autumn" Lines 15 and 14 from bottom, delete the lines Line 12 from bottom, delete "at all longitudes" Page 22-14, left column Delete lines 6 through 9 from top and substitute.: "In the South Pacific the belt of rough-to-high seas has moved southward and has frequencies of abOut 60% along its major (east - west) axis." Line 11 from top, for "80%" read "70%" Line 12 from top, for "520" read "500" 2. The enclosed revisions of Figures 22-62 through 22-65 replace those contained in the published Section. Declassified in in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 I50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ?? NAVY - JANUARY 1956 N I S 6 9 TABLE OF CONTENTS FOR SECTION 22 PONFIDENTIAL A. General 1. Summary Page 22 - 1 22- 1 2. Maps and charts 22 - 3 3. Landing places 22 - 3 4. Glossary 22 - 3 B. Oceanography 22 - 4 1. General 22 - 4 2. Tides 22 - 4 a. General 22 - 4 b. Tidal currents 22 - 7 3. General circulation 22 - 9 a. Surface circulation 22 - 9 CONFIDENTIAL (1) General 22- 9 (2) East Wind Drift 22 - 9 (3) West Wind Drift 22 - 10 b. Subsurface circulation 22 - 11 (1) General 22 - 11 (2) Antarctic Surface Water 22 - 11 (3) Deep Warm Water 22 - 11 (4) Antarctic Bottom Water 22 - 12 4. Sea and swell 22 - 12 a. General 22 - 12 b. Open water distribution by season 22 - 13 (1) Summer 22 - 13 (2) Autumn 22 - 13 (3) Winter 22 - 13 (4) Spring 22 - 14 c. South of the ice limits 22 - 14 d. Local effects 22 - 14 5. Sea water characteristics 22- 14 a. Physical properties 22 - 14 (1) Introduction . 22 - 14 (2) Temperature 22 - 16 (3) Salinity 22 - 21 (4) Density 22 - 27 (5) Electrical conductivity 22 - 31 (6) Buoyancy 22 - 31 (7) Color and transparency 22 - 31 b. Ice 22 - 40 (1) General 22 - 40 (2) Pack ice 22 - 40 (3) Icebergs 22 - 44 (4) Accessibility of coast 22 - 44 c. Sound conditions 22 - 45 (1) Sonar 22 - 45 (a) General 22 - 45 (b) Area 69 22 - 45 1) General 22 - 45 2) Layer depth 22 - 47 3) Echo ranging 22 - 48 (2) Solar 22 - 50 PAGE 22-i 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL MILITARY GEOGRAPHY NAVY?JANUARY 1956 Page 6. Geology 22 - 51 a. Structure 22 - 51 b. Bathymetry 22 - 51 c. Bottom sediments 22 - 54 d. Geophysics 22 - 55 ? (1) Gravity 22 - 55 (2) Seismicity 22 - 55 (3) Magnetism 22 - 58 7. Marine biology V 22 - 60 a. Attachment fouling 22 - 60 (1) General 22 - 60 (2) Geographic variation V 22 - 60 (a) Subantarctic region 22 - 60 (b) Antarctic region 22 - 62 b. Borers 22 - 62 c. Algae 22 - 62 (1) , General 22 -62 (2) Geographic distribution 22 - 62 (a) Subantarctic region V 22 - 62 (b) Antarctic region V V 22 - 62 (3) Plankton 22 - 62 (4) Seagrasses V V 22 - 62 d. Bioluminescence (Phosphorescence) 22 - 62 (1) General 22-62 (2) Geographic distribution 22 - 63 (3) Seasonal variation 22 - 64 e. Dangerous marine animals 22 - 65 f. Human survival in water V 22 - 65 g. Sonic marine animals 22 - 65 (1) Sonic fishes 22 - 65 (2) Sonic mammals 22 - 65 h. Deep scattering layer 22 - 66 (1) General 22 - 66 (2) Geographic occurrence ? 22 - 66 C. Coastal Sector 1: Palmer Peninsula, South Orkney Islands, and South Shetla,nd Islands 22 - 67 1. General 22 - 67 2. Coast and landing places 22 - 67 D. Coastal Sector 2: Western entrance of Carroll Inlet to Cape Colbeck, including Peter I Island 22 - 75 1. General 22 -75 2. Coast and landing places 22 - 75 E. Coastal Sector 3: Ross Sea Area from Cape Colbeck to Cape Adare . 22 - 77 1. General 22 - 77 2. Coast and landing places 22 - 77 F. Coastal Sector 4: Cape Adare to Cape Adams ?22 -,81 1. General 22-81 2. Coast and landing places 22 - 82 G. List of sources 22 - 88 PAGE 22-ii CONFIDENTIAL 50X1 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY-JANUARY 1956 Fig. 22-1 Fig. 22-2 Fig. 22-3 Fig. 22-4 Chart Chart Chart Diag. NIS 69 LIST OF FIGURES Type of tide Cotidal chart Tide ranges Tide curves CONFIDENTIAL Page 22 - '5 22 - 6 22 - 7 22- 8 Fig. 22-5 Chart Tidal currents 22 - 9 Fig. 22-6 Chart General surface circulation 22 - 10 Fig. 22-7 Diag. Current speed with depth 22 - 11 Fig. 22-8 Diag. Subsurface circulation 22 - 12 Fig. 22-9 Chart Mean position of the Antarctic Conver- gence and the Antarctic Divergence; lo- cations of vertical sections 22 - 15 . Fig. 22-10 Chart Average surface temperature, August 22 - 18' Fig. 22-11 Chart Average surface temperature, November 22 - 19 Fig. 22-12 Chart Average surface temperature, February 22 - 20 Fig. 22-13 Chart Average alrface temperature, May 22 - 21 Fig. 22-14 Chart Deviation from the mean temperature by latitude, summer 22 - 22 Fig. 22-15 Chart Deviation from the mean temperature along lines equidistant from the conti- nent, summer 22 - 23 Fig. 22-16 Chart Average surface salinity, August 22 -'24 Fig. 22-17 Chart Average surface salinity, February 22 - 25 Fig. 22-18 Chart Average surface density, August 22 - 26 Fig. 22-19 Chart Average surface density, February 22 - 27 Fig. 22-20 Chart Average surface electrical conductivity, August 22 -28 Fig. 22-21 Chart Average surface electrical conductivity, February 22 - 29 Fig. 22-22 Diags. Composite vertical section, Atlantic Ocean, winter 22 - 32 Fig. 22-23 Diags. Composite vertical section, Atlantic Ocean, summer 22 - 33 Fig. 22-24 Diags. Composite vertical section, Indian Ocean, winter 22 - 34 Fig. 22-25 Diags. Composite vertical section, Indian Ocean, summer 22 - 35 Fig. 22-26 Diags. Composite vertical section, Pacific Ocean, winter '22 - 36 Fig. 22-27 Diags. Composite vertical section, Pacific Ocean, summer 22 - 37 Fig. 22-28 Diags. Representative vertical section, Weddell 22 - 38 Sea Fig. 22-29 Diag. Representative vertical section, Ross Sea 22 - 39 Fig. 22-30 , Fig. 22-31 Chart Chart Accessibility of Antarctic coasts; extreme iceberg limit , Mean limits of pack ice, April ? August .22 - 41 22 - 42 Fig. 22-32 Chart Mean limits of pack ice, September -- 22 - 43 March Fig. 22-33 Diags. Sound refraction patterns 22 - 46 Fig. 22-34 Chart Average layer depth, summer 22 - 47 Fig. 22-35 Chart Echo ranging conditions, summer 22 - 48 Fig. 22-36 Chart Maximum surface echo ranges on s'ubma- rine with 25.5-kilocycle sonar .(QHB?) 22 - 49 Fig. 22-37 Chart Structural trends 22 - 52 Fig. 22-38 Chart Observed gravity 22 - 55 ' CONFIDENTIAL PAGE 22-ii:50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part- Sanitized Copy Approved for Release @50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL MILITARY GEOGRAPHY NAVY-JANUARY 1956 Page Fig. 22-39 Chart Free air gravity anomalies 22 - 56 Fig. 22-40 Chart Earthquake epicenters 22 - 57 Fig. 22-41 Chart Volcanoes 22 - 58 Fig. 22-42 Table Active volcanoes 22 - 59 Fig. 22-43 Chart Magnetic anomalies 22 - 60 Fig. 22-44 Chart Southern auroral zone 22 - 61 Fig. 22-45 Table Magnetic ranges, southern auroral zone 22 - 61 Fig. 22-46 Chart Marine algae 22 - 63 Fig. 22-47 Chart Bioluminescence 22 - 64 Fig. 22-48 Chart Tracks and station Where DSL has been 22 - 66 Observed Fig. 22-49A Aerial Coastal Sector I. liception follows page 22 - 94 Island Fig. 22-49B Aerial Coastal Sector 1. Marguerite Bay , do Fig. 22-50A Aerial Coastal Sector 2. Northern extremity of do Peter I Island Fig. 22-50B Aerial Coastal Sector 3. Kainan Bay. Landing place (27) do Fig. 22-51A Aerial Coastal Sector 3. Kainan Bay. Landing place (27) do Fig. 22-51B Aerial Coastal Sector 3. Kainan Bay. Landing place (27) do Fig. 22-52A Aerial Coastal Sector 3. Bay of Whales. Land- ing place (38) do Fig. 22-52B Aerial Coastal Sector 3. Bay of Whales. Land- ing place (28) do Fig. 22-53A Photo Coastal Sector 3. West of Bay of Whales do Fig. 22-53B Aerial Coastal Sector 3. Ross Island at Cape do Evans. Landing place (32) Fig. 22-54A Aerial Coastal Sector 3. McMurdo Sound do Fig. 22-54B Photo Coastal Sector 3. Franklin Island do Fig. 22-54C Aerial Coastal Sector 4. Coastal area near Cape do Folger Fig. 22-55A Photo Coastal Sector 4. Ice-free coastal area at landing place (54) do Fig. 22-55B Aerial Coastal Sector 4. Vestiold Hills. Land- ing place (63) do Fig. 22-56A Aerial Coastal Sector 4. SOrsdal Glacier tongue do Fig. 22-56B Aerial Coastal Sector 4. Larsemann Hills do Fig. 22-57A Aerial Coastal Sector 4. Byrd Bay. Landing place (75) do Fig. 22-57B Aerial Coastal Sector 4. Byrd Bay. Landing place (75) do Fig. 22-58A Aerial Atka Bay. Landing place (76) do Fig. 22-58B Photo Ross Sea. Pack ice do Fig. 22-59A Photo Ross Sea area. Pancake ice do Fig. 22-59B Aerial Ross Sea. Scattered sea ice and brash do Fig. 22-60A Aerial Atka Bay. Tabular bergs do Fig. 22-60B Aerial McMurdo Sound. Sea ice do Fig. 22-61A Photo Western Ross Sea. Pack ice do Fig. 22-61B Photo McMurdo Sound area. Large berg do Fig. 22-62 Chart State of sea, summer do Fig: 22-63 Chart State of sea, autumn do Fig. 22-64 Chart State of sea, winter do Fig. 22-65 Chart. State of sea, spring do Fig. 22-66 Chart Swell, summer do Fig. 22-67 Chart Swell, autumn do PAGE 22-iv CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY - JANUARY 1956 NIS 69 CONFIDENTIAL Follows page Fig. 22-68 Chart Swell, winter 22 - 94 Fig. 22-69 Chart Swell, spring do Fig. 22-70 Diags. Average depth of the sound channel, sum- mer, and vertical sections of sound ve- locity do Fig. 22-71 Chart Major bathymetric features do Fig. 22-72 Chart l3athymetry do Fig. 22-73 Chart Bottom sediments do Fig. 22-74 Charts Occurrence of whales, November - March do Fig. 22-75 Chart Location map for oceanography do Fig. 22-76 Map Landing places do CONFIDENTIAL This Section was prepared for the NIS by the Office of Naval Intelligence with the Navy Hydro- graphic Office contributing the data on oceano- graphic conditions. PAGE 4450X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY ? JANUARY 1956 A. General MILITARY GEOGRAPHY 22. Oceanography and Coasts 1. Summary The continent of Antarctica, almost twice the size of the United States, is unlike other continents in that it is separated from surrounding land masses by miles of open sea. The nearest land mass, South America, lies about 560 n. miles* away. Antarctica lies about 1,700 n. miles from Australia and 2,100 n. miles from Africa. The in- tervening sea areas are often rough, windy, and cold. The coasts of Antarctica, which total about 14,000 miles in length, are in general inhospitable. Nevertheless, at least 61 Antarctic expeditions have landed on at least 81 different landing places on and near the Antarctic continent (FIGURE 22-76). Most of the landings were made on or near the Palmer Peninsula south of South America, and in the Ross Sea area south of New Zealand, the two most approachable areas of Antarctica. With the exception of the landings effected by the U.S.S. Atka expedition of 1954-55, the landings made after 1950 are not covered in this Section; several photographs from "Operation DEEPFREEZE," which were received during publication of this Section, have been included. The approaches to Antarctica are usually ob- structed by a broad belt of pack ice" that lies as far as 1,000 n. miles offshore. In general, the belt extends northward to about 65?S. in the Pacific Ocean and eastern part of the Indian Ocean, and northward to about 56?S. in the Atlantic Ocean and western part of the Indian Ocean. During the summer months the belt of pack ice retreats south- ward and is usually backed by a broad belt of open water, but in some areas the pack disap- pears. In the southward approach to the belt of open water it has been found that during the summer the belt of pack ice to the north may be traversed or by-passed more easily along certain meridians. These favorable avenues of approach are along the Greenwich meridian, between the 70?E. and 90?E. meridians, and along the 180? meridian. The approach from the north to the * In text, distances are in statute miles unless nauti- cal miles is specifically indicated by "n.," as "14 n. miles." ** Selected ice terms used in this Section are defined in Subsection A, 4. CONFIDENTIAL CONFIDENTIAL west coast of the Palmer Peninsula also is seldom obstructed by pack ice during the summer months. In addition to the previously mentioned belt of pack ice and the belt of open water to the south, many coasts are immediately bordered by ice that may extend several hundred miles seaward but usually extends perhaps 20 to 80 n. miles offshore. Most of this is pack ice, though some areas may consist of shelf ice and glacier ice tongues. The ease with which the pack ice may be penetrated by an icebreaker varies from time to time and from place to place. The occurrence and density of pack ice along coastal areas and in sea areas ex- hibit varying degrees of annual regularity. Some areas are consistently encumbered year after year, and other areas are only occasionally encumbered. Near the mainland the pack ice usually grades into sea ice, which often can be landed upon. Also, near the mainland it is not uncommon to find broad leads of open water. In most waters around Antarctica, depths are comparatively great. Aside from the ice, the chief navigational danger lies in the possibility of running aground on uncharted rocks in the vicinity of islands and islets. Most of these areas are poorly charted and depths differ greatly within short distances. The uncertainty of pack-ice conditions off many coasts prevents definite evaluation of landing pos- sibilities. Also, with the advent of more power- ful icebreakers, coasts that formerly were consid- ered to be unapproachable may soon be accessible. The weather of Antarctica is a highly variable, though most formidable, obstacle to landings. Some areas are subject to prolonged periods of violent winds and sudden blizzards that reduce visibility to zero. A phenomenon restricted to polar areas is the cloudy-bright "white-day" or "white-out," a weather condition in which no ob- ject casts a shadow, the horizon becomes indistin- guishable, and only very dark objects can be seen. Some stretches of the coast of Antarctica have in the past been unapproachable throughout the year on account of the dense pack ice. Such areas include most of the south and west coasts of the Weddell Sea, which lies east of the Palmer Penin- sula. Other unapproachable coasts are the coast between the Palmer Peninsula and the Ross Sea, most of the coast between 152?E. and 170?E., the coast between about 115?E. and 139?E., and be- PAGE 22-150X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 !Th Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL N I S 6 9 NAVY - JANUARY 1956 tween about 30?E. and 50?E. Some stretches of coast are almost always approachable during the summer. These areas include the west coast of the Palmer Peninsula, the South Orkney and South Shetland Islands, and the Ross Sea area. Many stretches of the remaining coast of Ant- arctica lying east of the Weddell Sea and west of the Ross Sea can usually be approached during the summer. These areas include the coast between 140?E. and 143?E., between 89?E. and 95?E., and most of the coast between 58?E. and 81?E., as well as the ice cliffs bordering New Schwabenland astride the Greenwich meridian. Tides are diurnal (one high water and one low water each day) in the southern Atlantic and Pa- cific Ocean areas, but are mixed (two unequal high waters and/or two unequal low waters each tidal day) in the southern Indian Ocean area. In gen- eral, tidal currents tend to flood in a counter- clockwise direction around the continent and- ebb in the reverse direction. South of about 65?S., waves are usually from the northeast and winds are generally from the east and northeast, result- ing in a, current setting to the southwest. North of 65?S., high waves that generally progress east- ward occur during all seasons and the prevailing westerly winds produce a surface current that sets to the east or northeast. Most coasts of Antarctica are covered by great depths of snow and ice that extend seaward beyond the shoreline and terminate in vertical ice cliffs approaching 200 feet in height. Where the sheet of snow and ice extends many miles out to sea it is called shelf ice. Along the coasts where the ice cliff stands nearly on the shoreline, cliffs or head- lands of bare rock interrupt the vertical ice cliff. On the back side of the headlands, or where the ice edge has retreated inland, the edge of the ice sheet commonly terminates against a low ridge or bank of rocks and rock fragments called a mo- raine. In some of the Antarctic areas such as the South Orkney Islands, the South Shetland Islands, part of the Palmer Peninsula, and the west coast of the Ross Sea, hills and mountains are free of snow and ice during the summer except for glaciers. Most low shores, however, are still guarded during the summer by vertical ice cliffs, and only the steepest shores are usually free of snow and ice. Antarctic terrain that is free of snow and ice is composed of bedrock, eithei bare or covered by morainal material, and is essentially devoid of soil and vegetation. On Antarctica, beaches as normally defined in the SECTION 22 of the NIS are rare. Landings in this Area are usually made on sea ice, on shelf ice, or on shores of morainal material or bedrock. The simplest and most common landing is made di- rectly from ship to sea ice, with the ship tying up PAGE 22-2 alongside the sea ice, which forms a natural ice wharf standing perhaps 2 to 4 or more feet above sea level. The chief disadvantage of a sea-ice landing is that a firm and safe base still has not been achieved and there may be pressure ridges, open leads, tidal cracks, or vertical ice cliffs between the landing place and the objec- tive. Landing can also be made directly on shelf ice, which stands many feet higher than sea ice, provided the vessel can penetrate to the shelf. The major difficulty in making a boat landing on an island or on the mainland is the steep slope of most shores, which makes egress from the landing site difficult and prevents secure beaching of the boat. Also, all heavy cargo must be lightered ashore. A comparatively recent innovation in landing on Antarctica has been the utilization of both fixed-wing aircraft and helicopters. Information on landings in the Antarctic area was derived mainly from the List of Expeditions prepared in 1955 by the Board on Geographic Names. This list, which is complete through ex- peditions originating in 1950, is incorporated in the Antarctica gazetteer published in 1956. Additional sources of information were the official reports of i the U.S. Navy "Operation WINDMILL" of 1947-481 and the expedition of the icebreaker U.S.S. Atka in 1954-55. The chief sources of information on the coasts and hydrography in the Antarctic area were the USHO charts available in December 1955, and the USHO Sailing Directions for Antarctica, 1943, H.O. Pub. No. 138, corrected through July 30, 1955. Other sources included Roscoe's "Contribu- tions to the Study of Antarctic Surface Features by Photogeographic Methods," and a report on the Scott Expedition of 1910-13, which included helpful maps and survey notes. In general, the maps and charts of Antarctica are lacking in -detail, and the portrayal of the coastal configuration is highly generalized. Some local areas, however, are almost completely uncharted, whereas others are charted in great detail. On ac- count of the wide differences in chart coverage and the small scale of the landing place map (FIGURE 22-76) , all distances, coordinates, and elevations given in the text were taken from what were con- sidered to be the most reliable sources, and may be slightly at variance with the landing place map. In this Section, oceanographic coverage extends north to 50?S. latitude and coast and landing places coverage extends north to 60?S. latitude. The ad- ditional coverage for oceanography is to include consideration of the Antarctic Convergence Zone. To facilitate describing the coasts the Area is divided into four coastal sectors which are num- bered counterclockwise around the continent. Coastal Sector 1 consists of the Palmer Peninsula and nearby islands, the South Orkney Islands, and CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY ? JANUARY 1956 MILITARY GEOGRAPHY the South Shetland Islands. Coastal Sector 2 con- sists of the coast between the Palmer Peninsula and the Ross Sea, including Peter I Island to the north. Coastal Sector 3 consists of the coasts of the Ross Sea. Coastal Sector 4, by far the largest coastal sector, extends counterclockwise from the Ross Sea to the base of the Palmer Peninsula. The coastal description of each sector proceeds in a counter- clockwise direction. 2. Maps and Charts The base for the landing place map (FIGURE 22- 76) is USHO Chart 2562. Other USHO charts, the new 6000 series, cover Antarctica at a scale of 1:1,500,000 except for the coast between about 35?E. and 165?E. The charts covering the gap are at present under preparation and will be available soon. Complete coverage of Antarctica is available in British Admiralty charts. Many of these are at a small scale and out of date; others, however, are at larger scales and afford very good coverage. The U.S. Hydrographic Office has reproduced a number of Norwegian charts, at a scale Of 1:250,000, that were compiled from air photos and are now part of the USHO 16321 series. Similarly, a few large- scale Argentine charts have been reproduced as the USHO 16430 series. Other coverage consists of the three U.S. Department of Interior 1:1,000,000 pro- visional charts of the Wilkes Land, the so-called Blodgett series; and four French nautical charts and four topographic maps of the Adelie Coast. Other charts are those made by the American Geo- graphical Society at a scale of 1:3,000,000; the Ger- man charts of the Kosack series at a scale of 1:4,000,000; and the World Aeronautical Charts at scales of 1:1,000,000, 1:3,000,000, and 1:5,000,000, each series covering the entire coast of Antarctica. 3. Landing places Because of the unpredictability of the ice condi- tions near or on most coasts of the Antarctic area, and the lack of information, no attempt has been made to select, evaluate, or fully describe landing places. As an alternative the site of each landing made by Antarctic expeditions through 1950 and the expedition of the U.S.S. Atka in 1954-55 is shown on a landing place map (FIGURE 22-76) . The landing places indicated on the map include landings made from ship to shore by boat or air- craft, and landings made from ship to sea or bay ice and thence to the shore on foot or by vehicle. Also included are landings made by aircraft from ice close by the ship to the ice close by an island or the mainland and thence on foot or by vehicle to the shore. Not considered as landing places are points reached by cross-country movement or by aircraft from other landing places. The fact that CONFIDENTIAL CONFIDENTIAL a landing has been made in an area is indicative of the favorable conditions that may prevail there. Common features of nearly all Antarctic landings have been the relative difficulty and small scale of each operation. 4. Glossary The following ice terms have been used in describ- ing the coasts and oceanography of Antarctica: TERM MEANING bay ice young, flat ice of sufficient thick- ness to impede navigation. In the Antarctic this term also has been used at times for heavy landfloes. berg iceberg. bergy bit a medium-sized fragment of gla- cier ice, heavy floe, or hum- mocky pack ice, washed clear of snow and floating or aground. A typical bergy bit is about the size of a small cottage. brash small fragments of sea ice less than 6 feet in diameter. calving the breaking away of a mass of ? ice from an iceberg, glacier, or shelf ice formation. continental ice . . ice which inundates a large land ? mass; the surface contours of the land are not revealed on the upper surface of the ice. crevasse a fissure or rift in glacier, shelf ice, or land ice formation due to temperature _changes or mo- ? tion of the ice. fast ice' all types of ice, either broken or unbroken, attached to the shore, beached, stranded in shoal water, or attached to the bot- tom of shoal areas. floe term used for referring to frag- ments of ice with no speCified size intended. glacier berg an iceberg usually bluish or green- ish in color, smaller than a tabular iceberg, with little or no snow cover and often con- taining many crevasses.' glacier a flow of land ice from an area of accumulation. growler a small fragment of ice awash, smaller than a bergy bit, usually of glacial origin, and generally greenish in color. highland ice a comparatively thin but continu- ous ice sheet overlying any flat or undulating land surface and conforming to a considerable extent to the irregularities of the land upon which it rests. iceberg a mass of land ice that has broken away from its parent formation on the coast, and either floats in the sea or is stranded on a shoal. PAGE 2250X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 TERM MEANING ice cliff the cliff-like front of a glacier or of shelf ice where it meets the sea. icepack any large area of floating ice driven closely together. ice shelf a thick formation with level sur- face extending seaward from the land to which it is attached. land ice any ice formed on land masses, as' an icecap or glacier. lead a long, narrow, but navigable water passage in pack ice. moraine a ridge of rock debris deposited by a glacier. nunatak an isolated hill or mountain of bare rock rising above the sur- rounding ice sheet. pack ice any large area of floating ice driven closely together. pack icepack or pack ice. pancake pieces of newly formed ice usu- ally between 1 and 6 feet in diameter ' with raised *rims and circular appearance. piedmont ice an ice sheet formed by the coales- cence of ice spreading out from two or more wall-sided or val- ley glaciers over a compara- tively level plain at the base of the mountain slopes down which the glaciers descend. pressure ice sea ice having the surface rough- ened by the action of wind, cur- rent, tide, and temperature changes. Pressure ice refers to a disturbed growth and develop- ment. pressure ridge pressure ice in the form of a ridge. ramp an accumulation of snow that forms an inclined plane between land or land ice elements and sea ice or shelf ice. sludge an accumulation of small pieces of soft ice mixed with slush; has a slight hardness. sea ice ice formed by the freezing of sea water. shelf ice a thick formation with level sur- face extending seaward from the land to which it is attached. tabular berg a mass of ice calved from shelf ice,' with a flat upper, surface and with at least the upper por?-? tion formed from stratified snow or more or less loose, granular ice in transition from snow to glacier ice; color changes with weathering, from original daz- zling white to blue. tide crack a crack in sea ice, usually paral- lel to the shore, caused by the rising and falling tide. PAGE 22-4 B. Oceanography 1. General NAVY?JANUARY 1956 This subsection includes oceanography for off- shore and nearshore waters and geology for sub- marine areas and the entire continent of Antarc- tica. Since most of the nearshore region of NIS 69 is covered by ice, the oceanographic topics are primarily concerned with the offshore ice-free regions. In order to include discussion of the Antarctic Convergence Zone, which is a natural oceanographic boundary for the waters of this Area, the northern limit of the subsection is ex- tended to approximately 50?S. latitude, which em- braces the southern tip of Smith America and many of the oceanic islands and island groups not included in other Sections of this NIS. The polar continent is roughly circular and al- most entirely covered by a mantle of ice. Beaches and landing sites are sparse and the coast is char- acterized by frequent and almost vertical ice cliffs. Surrounding the continent and extending far sea- ward is an immense field of pack ice, which re- stricts access to the continent to the brief summer period. In the open water region north of the pack the prevailing winds influence the direction and magni- tude of the surface currents and waves. The major belt of winds is the westerlies, which generally lie north of about 65?S. In this belt rough-to-high sea ,and swell is common the year round; direction of both waves and currents is from the west. South of the prevailing westerlies waves and cur- rents are primarily from the east under the influ- ence of the Polar easterlies. 2. Tides a. GENERAL ? Tidal observations on the Ant- arctic continent are not sufficient to provide an adequate description of the tides along most of the coast. The information illustrated on FIG- URES 22-1, 22-2, and 22-3 is based primarily on data from the stations shown on the tide range chart (FIGURE 22-3), along with additional data from the islands and land areas to the north. As new data become available in the future, changes in these charts may be necessary. Both mixed tides (two markedly unequal high waters and/or two markedly unequal low waters each tidal day) and diurnal tides (one high water and one low water each tidal day) occur along the Antarctic coastline (FIGURE 22-1). Tide curves for each of these types of tide are illustrated in FIGURE 22-4. CONFIDENTIAL 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? NAVY ?JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL FIGURE 22-1. TYPE OF TIDE In the vicinity of Ross Island (14),* the tide is diurnal or nearly so for the entire month, while off Adelie Coast (5) and Palmer Peninsula the tide is completely diurnal only near the time of maxi- mum north or south lunar declination and quad- rature. On the Adelie Coast the inequality is in the high water, whereas off Palmer Peninsula the inequality is in both the high and low waters. North of about 65?S., the tide becomes mixed with the inequality in the low water. Northward from the South Shetland and South Orkney Islands to * Italic numbers in parentheses following place names refer to locations shown on FIGURE 22-75. CONFIDENTIAL South Georgia, the tide gradually changes from mixed to nearly semidiurnal, as it also does in the regions around Heard and Macquarie Islands. Westward of about 138?E., the tide is mixed with the inequality in the high water, probably becom- ing diurnal again somewhere between 700 and 10?E. The progression of the high water of the, prin- cipal lunar semidiurnal tide (M2) is presented in the cotidal chart (FIGURE 22-2) . Numerals repre- sent the sequence of progression, time of high water of the partial (M,) tide, and the approximate time of observable high water in all but the diurnal re- gions. Two nodal points of amphidromic systems are within the limits of this Area. The first, in a ? 50X1 PAGE G2-a Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL ' NIS 69 NAVY?JANUARY 1956 130?W 20W 110?W 100W 90? EST 8aw 7V EO? 50?W sou ? 1CA 140? 0 / 11 12 10 il. .. 40. 150? 4 -------?, -----.....?.." 9 70? ..-t 30? w 160. 4PPNN 10 / -- r, N , 9 ------ e---- s 10 o 4111111111\ s o 1700, w V -.44IN 0 12 ?10? ------, , 9 111 w I 170? 1111Whi ,,,a,..7.,Levito,at a, ,A- 1)1 Sri T AR C TIC A ? a \ a a 2 , o Ale 11I -10? 1 1 VW - 41 t9 , ..... s s. 1 a )/ 3 2 . 150? LAS A .? * 140? E 130?E 120?E 110?E 100?E 90? EAST WE 70. 60?E 50?E FIGURE 22-2. COTIDAL CHART. Numerals indicate time of high water of the principal lunar semidiurnal tide (M2) in solar hours after upper and lower lunar transit of the Greenwich meridian at full and change of the moon. clockwise amphidromic system, is at about 17?E. The second is a degenerate nodal point, somewhere to the south of Ross Island. This partially ac- counts for the strong diurnal tide in that region. Tide ranges are shown in FIGURE 22-3. The largest ranges in the mixed and semidiurnal tide regions normally will occur near the time of new and full moon. In the diurnal portions, ranges usually will be largest near the time of maximum north or.. south declination of the moon. Insofar as tide ranges in the open ocean are unknown, the corange lines on FIGURE 22-3 indicate probable ranges. PAGE 22-6 It has been observed in the Arctic that a solid cover of stationary ice will materially alter tidal phenomena. With complete ice coverage, espe- cially shorefast ice, high water has been retarded nearly 4 hours, and the range of the tide decreased 4 to 5 times. However, along the edge of shelf ice there will be no apparent tide since the ice shelf is a floating mass that rises and falls with the tides. This situation has been noted at Queen Maud Land and along the Ross Ice Shelf. Fluctuations of water level ascribed to winds may be of particular importance in certain regions of the Antarctic. For example, high water marks CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? ? NAVY?JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 131rw izo.w lio?ve IOT W STWEST I 86 70?W 66W TRW 140? LEGEND SR ?SPRING RANGES TR ?TROPIC RANGES TIDE RANGES IN THE OPEN OCEAN ARE UNKNOWN. DASHED LINES INDICATE PROBABLE RANGES. ? / / / I.. . 1 / 3 60? 1 soon ....E.,.? /j 4,..? 9 81 ? 0 -.At. .,?. ., .oir -.?...--,65 111 40? 150? / / \ / PCRT 5 LEN' RE CHANNEL IPORT LoCKROY IF TR 4.8 i KIN' ED ? D COVE 1 TR 4.5 ---, PUERTO MEL? IOR R 2.5 /PORT CHARCOT4 / R 4.1 TR 4 : PORT 'OSTER CIRC. CISION 1,4 ....._ R 5.0 /. TR 5 fatt,tcrn.,..? HOPE TH HARB 3V ISO? W .4 \ I ARGENTINE IS ANDS ,....? ,ar. t 'TR 5.4 4r401,""' SNO HIL61'_\/ NO \ Airrre?. t R7.9 T 42 t..- ? '4RA ,1 1 / \ / b SCOTIA BAY I SR 5.0 I -..?,? . - t?\-,- 5 4 ? NAN N ISLAND 4 ...r ' ? gi-, I No? 's , ? _ .. /1110! KO HARBOR r/ IR 5.7/ , AR , :1 o TONI TO LAND / P. SR 2.7 L ? 1 170* 1ST N. \ \ \ Sr \ / , . : A I A NE / i 0 7 .. .---' r, 4 q f P)-,. , ? ..1, /It t,'7,- 70? so. I .9/ / I ' "V / oi. t% ..." / I / SR IV 170.16 \/ 1 /MACQUARIE ISL ...???/ ND CAPE EVANS /I TR 3.0 i 1 , /4 .t ,,,. CPE ARMITAGE 0. TR 3.1 / . A N T A R C T I C A I v>"--------CAPE R? ?S ,.., 2.7 T . 4. CAP DENISE ES' criCr .60 o o .? / / / ., .., , ..---' \ / / / if---------/---4 / i , I60? SR 2/4 / ....... \ , CAPE AARG IE ,. POIN E GE LOGI R CHER X : ? TR 4, 4 N D . . i 11*a 4 1 ,,i 1 ''',......." 111" 1ST GAUSS , \ _ TR/3.3 . r Tr NAMES ON THE CHART ARE THOSE GIVEN IN TIDE TABLES. NAMES DIFFERING FROM THE BGN APPROVED FORM ARE LISTED BELOW: 1 \ 60 11 TIDE TABLE." 13.011, BAHIA LSLA NENY? NENY BAY GAUSS STATION NOT APPROVED NANSEN ISLAND NOT APPROVED POINTE GEOLOGIE NOT APPROVED PUERTO MELCHIOR MELCHIOR HARBOR ROCHER X?? ROCK X ? ARGENTINE TIDE TABLES. ?? NOT FROM 1 I HEARD ISLAN. SR 2.3 I 3 - / - 4 Kr TIDE TABLES, SEE SOURCE 72. ./ IIVE 100?E STEAST SEE IRE 60.6 STE ' FIGURE 22-3. TIDE RANGES (FEET) , 1955 12 to 14 feet above normal high water have been reported in the South Shetland Islands. However, for most of Antarctica the strongest winds are the offshore winds which tend to lower the water level rather than raise it. Tidal predictions for some of the stations shown on FIGURE 22-3 can be obtained either from the U.S. Coast and Geodetic Survey publications Tide Tables, East Coast, North and South America and Tide Tables, Central and Western Pacific Ocean and Indian Ocean, or the British Admiralty pub- lication The Admiralty Tide and Tidal Stream Tables, Atlantic and Indian Oceans. CONFIDENTIAL b. TIDAL CURRENTS ? Tidal currents are the horizontal components of water movement ascribed to the influence of astronomical tide-producing forces. The duration of the tidal current in a par- ticular direction normally depends upon the rela- tive magnitude of the diurnal and semidiurnal com- ponent of the tide. This relation changes from place to place, as well as with change of phase and declination of the moon. When diurnal compo- nents predominate, the current may be expected to run in either direction (flood or ebb) for about 12 hours. When the tides are seinidiurnal, the flood and ebb currents will each set for periods of about 6 hours. When the tide is mixed, the tidal PAGE 4G ?? 50X1 - I Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 7 5 Lu 4 Lu Ll-3 2 PORT FOSTER 1 MAXIMUM DECLINATION /..--- / / -MSL / / / / \ \ I / \ \.. i , MINIMUM DECLINATION 2 4 6 8 10 12 14 16 HOURS 18 20 22 24 7 6 5 L.L1 4 Lu LL 3 2 00 MARGUERITE 1 1 BAY MINIMUM DECLINATION AND NEW OR FULL MOON \ N / ..."'' N N N / / MAXIMUM DECLINATION AND QUADRATURE 2 4 6 8 10 12 14 HOURS 16 18 20 22 24 FIGURE 22-4. TIDE CURVES FOR ANTARCTIC STATIONS current is characterized by a conspicuous differ- ence in duration and velocity between the two floods or two ebbs. Tidal current data for the Antarctic are prac- tically nonexistent except for a few scattered ob- servations for the Palmer Peninsula region, the Ross Sea region, and at the offshore islands. Else- where, tidal currents (FIGURE 22-5) are derived from the hypothetical progression of the semidi- urnal and diurnal components of the tide. As a general rule, tidal currents tend to flood in the di- rection of the tidal progression, with speeds vary- ing in proportion to the tidal range. In nearshore areas tidal currents set toward the land, entering bays and inlets; in constricted passages they may be of considerable importance. In the open water of this Area tidal currents are generally weak and rotary, and merely accelerate or reduce the prevail- ing current speeds. In general, tidal currents tend to flood in a counterclockwise direction, following the trend of the coast around the Antarctic continent, and ebb in the reverse direction. The direction of flow is diverted in the larger bights, such as the Ross and Weddell Seas, and locally by bays and seaward ice projections. For example, on the eastern side of Palmer Peninsula in the vicinity of Lockyer Island PAGE 22-8 NAVY - JANUARY 1956 (44) the tidal currents have been observed to flood strongly to the south and ebb to the north. At Paradise Harbor (28) on the western side of Palmer Peninsula, tidal currents have been observed to flood to the north-northeast with a maximum speed of approximately 0.6 knot at midtide level and ebb to the south-southwest with speeds of approxi- mately 0.4 knot. In the vicinity of the South Shetland Islands, generally one flood and one ebb occur every 24 hours. However, owing to the mixed type of tide, tidal currents are very irregular. Winds may also have a marked effect upon the tidal currents, not only by affecting the period and velocity but also by raising the tides beyond normal levels. In moderate weather, tidal currents probably run eastward and westward within about 6 miles from land. Outside this distance the current has been found to run with the wind at a rate of 1 knot. In the northern entrance to Yankee Harbor (32), tidal currents sometimes may attain a velocity of 5 or 6 knots. At Clothier Harbor (30), Robert Island (31), the current outside has been observed to start to run to the west at three-quarters flood in the harbor. In the South Orkney Islands swift currents and tide rips have been observed in the straits and nar- row channels. Large numbers of icebergs carried through the straits and channels by the tidal cur- rents often restrict navigation. Reports indicate a current of 4.0 knots during flood tide in the narrow channel between Spine Islet (40) and Cor- onation Island (42), and a strong current has been observed between Spine Islet and Larsen Islands (41). In Washington (38) and Lewthwaite (39) Straits, east of Coronation Island, a current of about 3.5 knots has been observed. In the vicinity of Coulman Island (10) in the Ross Sea the tidal currents appear to run north and south, 12 hours each way, the north-setting current being the stronger. Heavy drift ice usually is found in the channel between Coulman Island and Cape Jones (9) because of tidal currents and the prevailing southeasterly winds. Between Beau- fort Island (13) and Cape Bird (12) a strong cur- rent sets westward, which at times reaches a veloc- ity of 3.0 knots. Normally the strength of this current, but not its direction, is affected by the tides. Tidal currents greatly influence the break- out of the fast ice in McMurdo Sound (11). Tidal current observations off the Antarctic ice barrier in the vicinity of Norsel Bay (46) show current averages of less than 0.1 knot setting to- ward the west-southwest; that is, the current is directed approximately parallel to the main direc- tion of the coastline. - CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY - JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 130?W ? 120?W 110?W 100?W 90?WEST 80?W 70?W 60?W 50? 140? W LEGEND --... FLOOD CURRENT (EBB CURRENT SETS IN REVERSE \ DIRECTION.) 11, f.tICA Iltr W ? 150? \ \ . \ ----""--........,...?, / 7 ...? 160? ?.?_,...._. \ .,...`) .... \ \ 4 : 0- (4"?"' ?? .. ,'?'2 / 170? W ?EO r s.*?1 80. IS '. Oilt i IT" _ MSS /Cf SO. flf 70? i< go. (77 ' 0 .... A !...y. .... I"- s I.-Z ..770* \ . in) la 180. 170? I 1 I. ' ' , c , . . ....:/- A N T A R C T I C A . / o \ ( 2 ' U. 10? 16Cf \ . e 4.. 5 . ,,, 150? L... . ? if ' r fr . 130?E 120?E . 110?E 100?E 90?EAST 80?E 70?E 60?E 50?E FIGURE 22-5. TIDAL CURRENTS 3. General circulation a. SURFACE CIRCULATION (1) General? The major currents in this Area are the West Wind Drift and the East Wind Drift, which lie in regions dominated by westerly and easterly winds, respectively. Between these two drifts lies the Antarctic Divergence. The West Wind Drift is circumpolar, but the East Wind Drift is interrupted by the Palmer Peninsula, where it is deflected northward into the region of west- erly winds. Local deviations from generalized cur- rent directions and speeds shown on FIGURE 22-6 CONFIDENTIAL should be expected, since there is relatively little detailed information on the currents of this Area. (2) East Wind Drift ? This current results from the dominantly easterly winds (Polar easter- lies) that blow, around the periphery of the Ant- arctic continent. Originating from the Antarctic Divergence, a zone of upwelling which marks the boundary between the prevailing easterly winds and prevailing westerly winds, the East Wind Drift sets generally southwestward and terminates in a zone of sinking which surrounds most of the Ant- -arctic continent. However, it is entirely possible that during summer melt water from ice on the PAGE 22-4.50)(1 LDeclassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY ? JANUARY 1956 130?W 120.55. 110.5v 1001110 90?WEST g0W 70.07 60?W 50.10 -------------7.6.. \ 'A, \ '.11. ? Ny V-1.. ...\-- I .0 ? ,.. -11.- - - ............\''' ,./;??.?...\%"????\ )r. ,----- --,,,,L...... ,Jr- \- / \\A. Ar -..-- / / \ 44 \/ / / 7 '\ C':C? ? 0 //1 \ // /\/ / \ __ -4.- _ ---,, , ..4:0 ..,-1;;;:\ \/' .c -..... i i ??? -4r. ------7---.7 --11 ? -071?. -- \?'.6/;?-..k. ..\7? ,...?.:,...,,,,, / ? 1 A 30. w He lio? /11_ , 1 NI i\ ,/_,\' .. _ r.,,,, i / ,-;--- 4 I / ' A r\ .1 5 - ,' ' ' 1-4 I ? 0 / ,4?,4,-1,, \ , \ 1 ,,, 7 4 t I I' ,,,,.. ..? / , f 1", i I QJ I `,. 1 ---,r) i 1 , q.'-'? I 4 .---4 I or------ I 1,---?,-,_ _. ,t, ,--- , , -......_ .. ,\:-_____\ ?'y ---.. -... t 1 NI AZ '7'' )41. \ 'ns ik f\,,,. , ',9 ',11/4 o -? k lit \ ? \ \ . \ \ \ \ ->-\ \ 'it , , . , _ ,, , Nr..%5,?e , .o/k _ \"------- 7 xr no* t t 4 I I II kk .2:1:41 is_ d ") ''' 0 ' V) I ii ND' 0, '' 7?., i i O go. LEGEND NUMBERS INDICATE CURRENT SPEED IN KNOTS i. ?,-,.4., --Nic?cL, IAA \ - - -, \ A?????? .0 - A? \ \ \ so? 4 __. 1 < Ai DATA ADEQUATE \41 0 1 111 , k it 1 4 \ \ I 4?? k ,\ 1 14.1?/ , " ....... ...,...> 4 '' -..' ? - , , . ..... ? / N ... ,. ,,, ... 4 ..) .. c.;),`,.r.;,-..,-,-)--)K, 4 ? ? ..? ?,. /1' 1 . ----; ? Ti.- .. ,?:' .:1 r, , 1- r'',:t! ......?...__... , , . ?'..:: ? : ' -47, ti',,,?,,,z- ..- 0? TO -2? ? ? A ;2,.S,,,,S)? ....._. __... )?=1;`,`, ',"? 6 0 , 7 01? ..?2' ' V V' ' . ...., ? - ?r? 'WA" L . a . .. ) " _4 .?.'4., ? ? -=-6?OR>--- C, _?_, .? ,G" i i ,, ,. . .......,., A.- . .. ?., 313.75 1 L.k: -".'-.------1 34.00?J ....23?75j1$0 ? 50 34.25 .'......"--34.50 ?100 ? cc La 111 34.60 ? 150 x x 34.70 34.70 r**34 5 ', I - ? ? 1- 200 EL, 0 250 300 1 IOW 66*S SALINITY (PARTS PER THOUSAND) 70*S 77*S DEPTH (FEET) 0 0 0 0 ) 0 0 0 0 C 27.25 27.25 J 27.50 ............... ......./.---) ? 50 27.75 ? ? in-. 100 ix w 1- ........................?.................____.............._____:____ w 27.80 27.90 i / 7-18i00 ?150 ? ? m x 1- lIl g 250 300 I OW 66?S DENSITY (DENSITY OF 1.02800 REPRESENTED AS 28.00) 70*S 77'''S 0 ? N - Cu O LI1 0 0 0 O 0 0 0 0 DEPTH (METERS) 200 ? ? 1--? L.LI ----------.-----------------***..------, 400 SF ......?....?......?......?..------ _2 ..-. '-------..'.............--------......'....."""." . fh 600 ? ? o ----,.............._ _ 800 1000 ---/ =____.-------------------...< --io -------'...". -io-................. 1 .__, ? RELATIVE BUOYANCY LOCATION OF SECTION 60.w A LEGEND BUOYANCY ISOLINES DENOTE CHANGES IN BALLAST BETWEEN THE SURFACE AND ANY PARTICULAR DEPTH. ISOLINES ARE NUMBERED IN THOUSANDS OF POUNDS OF BALLAST FOR A SUBMARINE OF ? 2400 TONS SUBMERGED DISPLACEMENT AND A COMPRESSIBILITY OF 1400 POUNDS PER 100 FT. NEGATIVE VALUES INDICATE THAT 43 4> / THE DENSITY HAS LESS EFFECT ON BUOYANCY THAN DOES COM- PRESSIBILITY. 120?E CONFIDENTIAL FIGURE 22-29._ REPRESENTATIVE VERTICAL SECTION IN THE Ross SEA PAGE 22750X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 b. ICE (1) General ?Probably the greatest single factor influencing any operation in the Antarctic is the pack ice (FIGURE 22-58B) . During winter it completely surrounds the continent, forming an almost impassable barrier that extends on the average as far north as 56?S. in the Atlantic sector and to approximately 65?S. in the Pacific sector. Pack ice may be defined as any large area of float- ing ice driven closely together. It may include ice formed in the open sea, remnants of fast ice formed near the coastline of the continent, and seaborne detritus of land ice derived from the continent and the islands. The important characteristic of Ant- arctic pack ice which distinguishes it from that of the Arctic is the extreme heterogeneity of any particular field of pack: in one locality the ice may range from huge bergs and floes, many miles long and broad, to the ice crystals produced by super- cooling of the sea. In the Arctic, in contrast, the pack of a particular field of ice is more generally homogeneous, consisting of only one type. The pack-ice edge varies latitudinally with sea- son. It seldom exists as a straight east - west line, but follows a rather tortuous course with embay- ments and promontories extending for many miles into and out of the pack. Owing to the prevailing southeasterly winds, the pack has a definite drift toward the north and west. As a consequence of the westerly movement, a great piling up of pack ice occurs in the western part of the Weddell-Sea. This westward drift likewise will cause a consider- able piling up of ice on the eastern sides of ice tongues projecting from the continent. Another distinct feature of the ice in the Area is the tabular bergs (FIGURES 22-60A and 22-61B) . Formed by the calving of portions of shelf ice, these generally are immense pieces of ice which may be as long as 100 miles and as high as 200 feet above the waterline. The ice shelves from which these bergs are derived are in themselves an out- standing feature of the Antarctic area (FIGURE 22-58A) ; these great ice masses, sometimes many hundreds of miles in extent (for example, the Ross Ice Shelf) , present sheer walls of ice which bar access to the continent from the sea. In general, ice conditions in the waters sur- rounding Antarctica at any particular point are almost impossible to predict. For example, at the entrance to the Ross Sea, the summer band of pack ice with open water to the south may fluctuate in width from year to year from as much as 400 miles to as little as 1 mile. Glacier tongues and bays reported over many years of Antarctic ex- ploration have completely disappeared. For ex- ample, the Bay of Whales (16), long reported by expeditions into the Ross Sea sector (FIGURE PAGE 22-40 NAVY - JANUARY 1956 22-52A) , was found to have disappeared by summer 1955, its whole west side having broken off, carry- ing with it a portion of Little America IV. (2) Pack ice ?Mean limits of the pack ice by months are shown in FIGURES 22-31 and 22-32. These limits are based on observations from whal- ing vessels, voyages of the research ship H.M.S. Discovery, and numerous other expeditions to Ant- arctica. Because these are only mean limits, the charts should be used with caution since the actual position of the northernmost edge of the pack varies from year to year. It should also be noted that portions of these lines represent interpolations, particularly for winter, when data are very limited. Open water areas south of the mean limits are not shown, since these vary greatly. Many of the ob- servations of the pack ice were made while skirting the pack, no entrance being attempted. (a) ADVANCE OF THE ICE EDGE ? Freezing begins in late March or early April and progresses very rapidly through June (FIGURE 22-31) . The ice edge moves northward, reaching its maximum extent in September and October. This northward advance is attributable to two factors, one south of the main body of pack and the other at its north- ern edge. First, the pack is being fed constantly from the reservoir of land-ice formations and sheets of fast ice formed in place; this contribution of ice moves into and with the main body of pack to the north and west. Second, in addition to the ac- cession from the south and the subsequent move- ment of the pack, the ice edge advances through freezing of the open sea to the north. The initial indication of freezing of the sea is the formation of ice crystals in the form of thin plates of ice lying horizontally on the surface of the water. These increase in number until the sea is covered by a slush of a thick, soupy consistency. The slush generally does not exceed a thickness of 12 inches and causes the sea to assume a grayish or leaden color. Under these conditions, a ship may experience clogging of intakes through accumula- tion of this type of ice. If the sea remains 'per- fectly calm, a smooth sheet of ice is formed (FIG- URE 22-GOB). If the sea is affected by swell At the time of freezing, the ice sheet is sufficiently plastic to give with the undulations. However, as the ice sheet thickens it becomes more and more brittle until finally the whole mass may be broken up. The resulting pieces are rocked by the swell and in their constant collision with each other assume the form of pancake ice (FIGURE 22-59A) . Some of these smaller pieces may unite to form larger floes, which in turn acquire the pancake appear- ance. If the ice remains in place, the water freezes between the pancakes, and a continuous ice sheet is formed. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? NAVY - JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 40r RELIABILITY DIAGRAM E-EXCELLENT F-FAIR G-GOOD P-POOR VIIM. MU? nCOAST OCCASIONALLY ACCESSIBLE TO UNREINFORCED SURFACE VESSELS IN SUMMER COAST GENERALLY ACCESSIBLE TO UNREINFORCED SURFACE VESSELS IN SUMMER COAST INACCESSIBLE TO UNREINFORCED SURFACE VESSELS IN SUMMER EXTREME LIMIT OF ICEBERGS 130?E 127E IIPE 100?E 50? EAST 701 6VE STE FIGURE 22-30. ACCESSIBILITY OF ANTARCTIC COASTS; EXTREME LIMIT OF ICEBERGS The pack is being augmented constantly by the addition of precipitation in the form of snow and hoar frost. New ice also forms along the edges of cracks and pools. The nature of the ice edge in winter varies with local winds and seas. Four conditions may exist: 1) With periods of calm, ice crystals or sludge will be found to the north of the heavier pancake ice, though not normally north of the 29.3? F. isotherm; 2) when there is a strong and persistent southerly wind, new ice probably will form in the calm water in the lee of the heavier ice; 3) in winds with a northerly component, new ice does not form readily CONFIDENTIAL and much of the newly formed ice crystals, sludge, and pancake on the fringe of the main body will melt, causing an apparent retreat of the ice edge; 4) with wind blowing directly from the west, the scum of ice crystals may disappear, but the sludge ice will persist to the north of the pack in a mod- erately wide belt. At its maximum extent in September ? October,' the ice edge lies farthest from the continent in the Atlantic and western Indian sectors. It is prob- ably closest to the continent in the vicinity of the Palmer Peninsula and in the eastern Indian Ocean sector. PAGE 22-4150)(1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY - JANUARY 1956 1 V 150? 160? 170? 313? 170. 160? 150. 140. I3W I2OW 10 lW VW ST 7V W OW 50?W dY W IV IV 4V ? Vlir 62e /IIi ...- \ a 1 44 ,k--,-----1g / ?''cro,.i.,------- - '4.____.----" ' ' A " ? t) T? ? 7 7 4, 400 / , 11111110 uGUST \ pta ' MAI i .?, id. it 4 .:444, ... P?PII?t.? I 1, , "6 , 0 , . , ,.. ? m A ;40. .. /),Iij'11" .11. .051 ICE 5,4111 sy (iV I 1 ANT ARC,T.ICA. ,s, t".4?4444, 70. ,...,,, ', 2 ? . a il 11 I r I?011 I .10145- . vo?I tg- .., 130. E 120. E 11VE 163? E 93? EAST 80?E 70. 1 601 APRIL THROUGH AUGUST FIGURE 22-31. MEAN LIMITS OF PACK ICE, APRIL THROUGH AUGUST (b) RETREAT OF THE ICE EDGE ? The ice edge begins its retreat southward in November (FIGURE 22-32). There appears to be little melting between November and December except in the re- gion east of the Weddell Sea, where the current causes a tonguelike extension of pack ice toward the east. In this region a vessel approaching Ant- arctica along the Greenwich meridian in December of an average year may encounter a broad belt of pack ice from about 550 to about 61?S., reach open water south of this, and then at about 65?S. encounter pack which extends to the continent. The greatest recession of the pack ice occurs from December to January. Little melting occurs be- PAGE 22-42 tween February and March. The tongue of ice from the Weddell Sea probably never disappears completely, in summer, although its extent is di- minished considerably. The pack ice is at its min- imum in March and lies close to the continent ex- cept in the Weddell Sea and the region from 80?W. to 180?. The mean position of the ice edge as shown on the charts does not necessarily imply that the en- tire portion from the limit line to the continent is completely icebound, because open water often is found south of the pack limit in summer and pos- sibly in winter. For example, most of the Ross Sea is open in February ? March, the amount of CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? ? NAVY ? JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 130?W 120?W 110?W 100? W 93?WEST ET W 70?W 60? . 50W 140? r sou aa aV . . / ?CI ?3 \ , Cl'eC-%0?1 w-........,...........,,,,, - / ? eireoralir-? ? / 3e - \ 4,,45k 00' p,,c6 \ SO .\ 011 5 I.. N X \ S?il'" 16V N ,),, W .1 s _ / k ) 8, , \ ..."" _ ' ..,, /itt 13 \ ..---' / ikli. " .C- 01 .- o 20. W ' 170. ? 5V --ir 3.--(--1-----------11'ii cr cr jzo.ZZ , -----...?..??..4:-.? 4 -.- rcrikt .1,:e0,), wi,*, ,',(?;;;;',7'is - 67', , , ;toss Kr Pla, er V Icy.$_ 80 1--- ,,,,,,,,II:11111 ,..-- o --,',,, - -----'---? 1, J10. V _ 50 ivc,l? . 1t3. 170. I1,0? TV EL 0 7, .._?;Cs''f1ac---7? 1 ?tj \ ? ' ' c7:VOre \ S 5 o NT ARCTIC t / S / / N . / 4 t / te?04'fiY A ? \ \ \ \ \ \ \ \ Ft 0 A 0 a ? Z -... - 8,, 0, 0 , ' \ 4/ CO Z 4.1 . ci 'CC 141 03 Z 41 a IV 3EV I?.?I?, J A 1 t-IAR1 (OE Ire NCVEMBER SEPTEMBER . / \ -OCTOBER \ to? 130? E 120?E I IV E 100? E. 90? EAST EVE 70. E 60?E 50?E I FIGURE 22-32: MEAN LIMITS OF PACK ICE, SEPTEMBER THROUGH MARCH open portion depending on the width of the belt of pack ice lying at the entrance. Melting of the pack ice in the Ross Sea sector is probably very rapid, one observation having the disappearance of about 250 miles of pack in a little over 3 weeks. In contrast, however, the Weddell Sea is probably never completely ice free in summer, owing to the backing up of the westwardly drifting ice. In the Pacific sector there is generally little retreat of the pack, practically the entire area from Cape Col- beck (20) to the Bellingshausen Sea (25) being impenetrable because of the consolidated pack. South of about 71?S., the Bellingshausen Sea is probably never free of ice. CONFIDENTIAL (C) SPECIAL CONSIDERATIONS OF THE PACK ? The pack usually does not grade from . isolated streams of ice to close pack. Such conditions may be found, but ordinarily the ice is first seen as a solid white line on the horizon, soon barring fur- ther progress. As evident from the discussion pre- ceding, conditions and ice types found at the ice edge vary from season to season and with the lo- cality. In spring and summer small floes and brash commonly are met, although much larger floes are to be found a short distance within the pack beyond the action of swell (FIGURES 22-59B and 22-61A). In autumn and winter the outer fringe of the pack often consists of ice scum or PAGE 22-450X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 crystals grading into pancake ice and more sub- stantial floes. Thickness of the ice varies in dif- ferent localities. Floes which have drifted from the Weddell Sea tend to be hummocked, over- ridden, and very thick. In parts of the Pacific sec- tor, where it appears that the ice may grow in place for considerable periods, immensely thick toes are to be found. Several features of the pack which are of opera- tional significance may be cited. Antarctic pack ice generally is covered with more snow than that of the Arctic. This snow provides a cushioning effect, tending at times to hold a ship when the thickness of the ice does not warrant it. In 1955 the U. S. S. Atka found that there were times when because of heavy snow on top of the ice it was brought to a standstill in ice 4 to 6 feet thick which otherwise would not have hindered an icebreaker to any great extent. As long as a ship remains underway it is fairly easy, to penetrate this ice, but once it stops the snow adheres to the sides. Antarctic ice appears to be less buoyant than that of the Arctic. It will submerge to a greater depth and remain submerged for a slightly longer time before rising to the surface. This longer submergence time conceivably could cause dam- age to screws by sudden emergence of ice after it has been broken by the ship. Navigating in the pack along most of the coast of Antarctica is potentially dangerous, since sud- den changes in wind can lead to complications. The greatest danger from pack exists in an en- closed space. For example, a narrow strait or deep bay into which the wind blows directly is the worst of all locations. The regions to windward of prominent points in the coastline can be equally dangerous, since a sudden change or increase of wind may cause a ship to be carried into shore or beset in a matter of minutes. Pack ice which extends more than 3 feet below the surface is undercut at the waterline, some- times as much as 5 feet in the thicker floes. The U. S. S. Sennett found that when operating in this type of ice the stern of a submarine should be trimmed down so that the propeller guards are at least a foot and a half below the surface of the water. This protects the propellers from damage by pushing the pack clear. The Sennett also noted that when it passed through a lead in a pressure ridge, it had to be kept under way at all times, because once it became dead in the water the ice closed in quickly and rode up over the tank tops forcing the submarine down. (3) Icebergs ? The maximum northward extent of icebergs is shown in FIGURE 22-30. Bergs are present nearly everywhere in the Antarctic, both within the pack and in open waters north and south of the pack belt. They are detected PAGE 22744 NAVY - JANUARY 1956 easily by sonar and radar and therefore are not as serious a threat as they once were. Navigating in open water where icebergs are present poses very few problems, since with sonar and radar warning they can be avoided. In the pack, however, they are potentially dangerous. Since they may extend to considerable depth and move with the subsurface current, it is not un- common to see them drifting contrary to the move- ment of the pack, in which they can build up con- siderable pressure. Occasionally, icebergs give the illusion of contrary movement because they move more slowly than the pack, which surges past them. Probably the most dangerous features of ice- bergs are the submarine rams, or spurs, which lie below the waterline. These are formed in tabular and glacial bergs alike. Not only is there danger in striking one of these rams while navigating close to a berg, but the rams are subject to calving and may be buoyed up to the surface, producing a serious hazard even for large vessels. Open lanes to leeward of a berg are a common phenomenon in the pack. Sea and swell also are effectively reduced in the open water to the lee of bergs. They should offer, therefore, an ex- cellent location to effect transfer of materiel from one ship to another. However, some danger does exist. A sudden change in wind will alter the direction of movement of the surface water and ice, closing up the previously open lanes. In open water the greatest danger exists from the calving of portions of the bergs as well as of their rams; therefore, they should be given wide berth. (4) Accessibility of coast ?FIGURE 22-30 gives some idea of those waters of Antarctida which are usually navigable and the parts of the coast which are most likely to be inaccessible to unre- inforced surface vessels. The least accessible por- tions of the coast are in the sectors from approxi- mately 74?W. to 155?W. and the western shore of the Weddell Sea. The portion from 115?E. to -139?E. is probably inaccessible owing to the con- centration of glaciers in the region. In these areas it is doubtful if a complete breakup ever occurs. In some places the coast is almost always ac- cessible in summer. The best known of these are the western and a small portion of the eastern coasts of the Palmer Peninsula, and almost all of the coast in the Ross Sea sector. This does not mean that there is ice-free water all the way to this coast; for example, entrance to the Ross Sea near the 180? meridian may require traversing from 1 mile to 400 miles of pack ice. Practically everywhere near the coast of Ant- arctica some pack ice may be expected in all sea- sons. The outer limit of the area where pack ice is found only part of the year (FIGURE 22-30) coin- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? NAVY - JANUARY 1956 ,MILITARY GEOGRAPHY cides with the September ? October mean limit of pack ice as shown on FIGURE 22-32. Even though some regions are shown as being accessible only occasionally in summer the coast is not neces- sarily icebound. If the pack can be traversed, it may be found that the waters in some of the coastal bays and around some of the islands will be open. Because ice conditions in Antarctica are so var- iable from year to year, it is difficult to choose sites that would be suitable as bases of operations. In a survey conducted by the U.S. Navy in the sum- mer season of 1954-1955, several sites were sur- veyed as possible bases for the 1957-1958 Interna- tional Geophysical Year. Three sites were sug- gested: Kainan Bay (18) in the Ross Sea, Atka Bay (47) , and Admiral Richard E. Byrd Bay (48) on the Princess Martha Coast (45). These were found to be suitable in most respects, and a detailed ac- count of conditions in these bays will be found in Commander Service Squadron Four Report of U.S. Navy Antarctic Expedition, 1954-55, conducted by the U. S. S. Atka (AGB-3) . Locations surveyed, but not found suitable, were Discovery Inlet (15), Okuma Bay (19), Sulzberger Bay (21), and Nor- sel Bay (46). Bases located on shelf ice normally cannot be considered permanent, owing to periodic break- offs of large portions of the shelf. For example, on the Ross Ice Shelf a large segment of Little America IV was removed by pressure or calving, and Little Americas II and III were placed adja- cent to open water. The Bay of Whales (16), known for over a century and a shore base for five expeditions, has been subject to similar change. Past observations indicated that the western shore of the bay moved northward while the eastern side had a relative westward movement, resulting in a progressive narrowing of the entrance. During Operation HIGHJUMP in the summer season 1946- 1947, the bay mouth was approximately 400 yards wide (FIGURE 22-52A) ; a year later the mouth had narrowed to less than 200 yards. At the time of the 1955 visit of the U.S.S. Atka a considerable breakoff of the west shelf ice changed the bay completely, making it almost unrecognizable. C. SOUND CONDITIONS (1) Sonar (a) GENERAL - The expression "sonar conditions" is used in this subsection to describe the probable effectiveness of sonar based on ocean- ographic factors which influence underwater sound transmission. The factors include the variations of temperature, 'salinity, and pressure with depth, the depth of the mixed (isothermal) layer, and ambient noise. With the exception of ambient CONFIDENTIAL CONFIDENTIAL noise, these factors limit the horizontal range of the sound beam by refraction. Temperature and pres- sure are of greatest importance to calculations of sound velocities in the open ocean where salinity variations are comparatively small, and close ap- proximations of ranges can be made from a knowl- edge of temperature alone for ordinary, submarine operating depths. FIGURE 22-33 illustrates, by means of idealized sound ray diagrams, the refraction associated with the two temperature structures most common to Antarctic waters in summer. Pattern NOP is char- acterized by an isothermal layer above a negative gradient with a temperature reversal at depth. As the sound beam approaches the colder water, some of the rays are refracted upward and remain within the isothermal layer, while those greater than a critical angle are refracted initially through the thermocline, but when the tempera- ture gradient becomes positive these downward rays are refracted upward. Thus, to the depth of the bottom of the positive gradient, the water is completely insonified (permeated with sound) . Pattern MIKE is characterized by an isothermal layer above a negative gradient with no reversal at depth. Here the rays refracted downward through the thermocline never return to the sur- face, and a shadow zone is formed from which very weak or no echoes will return. The environmental factors contributing to sonar effectiveness are expressed singly or collectively as percentages of ideal conditions. Ideal condi- tions are assumed to exist when: 1) the layer depth (depth of the isothermal layer) is At least 450 feet; 2) the temperature difference between the surface and 30 feet does not exceed 0.1? F.; and 3) the wind force is no greater than Beaufort 1. (b) AREA 69 1) General ? The analysis of sonar con- ditions in Antarctic waters has been limited largely to summer, since the paucity of data precludes more than a cursory treatment of other seasons. Summer conditions may vary considerably, in some years being best developed in late January and rapidly deteriorating in early March, in other years extending into late March after attaining highest development in middle to late February. Because of this annual variability, data for 'only January and February have been used to evaluate average summer conditions. Listening range charts for this Area are not presented, due to in- sufficient data. The ice limits superimposed on the sonar charts cover only those nearshore waters which usually are inaccessible. It should be noted that mean pack-ice limits for the summer months extend much farther north. PAGE 22-4t_ 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY - JANUARY 1956 20? 0 50 1-2 :0LU 500 200 ,E 250 w 300 C' 350 400 450 30? TEMPERATURE (?F) 40? 50? 60? 70. GO? - 1 I MAXIMUM ECHO RANGES PERISCOPE DEPTH RANGE >2000 YARDS 0 NOP (NEGATIVE OVER TEMPERATURE (?F) o2 0? 40. 50? GY 70? 80? 50 ? II.- 100 LAJ 150 ? 200 ? I I- 250 ? CI. w 300 , ? 350 ? 400 ? 450 I I 1 I I 1 1 I 1 1111111111- 000 2000 RANGE (YARDS) POSITIVE GRADIENT) 3000 4000 MAXIMUM ECHO RANGES PERISCOPE DEPTH RANGE >2000 YARDS 7".11111111=r NO II No 11' k / STRONG ECHOES MOO MIKE (MIXED WATER) SHADOW ,ZONE 2000 3000 RANGE (YARDS) ESTIMATED PERISCOPE DEPTH RANGE WHEN THE PATTERN IS: THE PERISCOPE DEPTH RANGE IS: NOP 1 EQUAL TO THE SURFACE RANGE MIKE 2/3 TO 3/4 THE SURFACE RANGE 4000 FIGURE 22-33. SOUND REFRACTION PATTERNS ASSOCIATED WITH TYPICAL ANTARCTIC TEMPERATURE GRADIENTS - The thermal structures most eommon to the Area in summer are typified by the two -patterns illus- trated in FIGURE 22-33. A positive temperature gradient. (NOP pattern) at depths varying from 150 to 1,000 feet is indigenous to that part of the Area between the Antarctic Convergence and the Antarctic Divergence (see FIGURE 22-9) . South of the divergence, MIKE pattern is found. The .seasonal thermocline, restricted to depths aver- aging only about 100 feet, prevails throughout most of the Area. Exceptions are parts of the Weddell, 'Bellingshausen, and -Ross Seas, where isothermal layers to more than 450 feet persist throughout the year. Owing- to the comparatively warmer water at depth surrounding Antarctica, upward refraction is the predominant characteristic of sound propaga- tion in these waters. In regions of melting ice, a secondary positive gradient between 50 and 100 feet further enhances upward refraction. Where a positive gradient occurs at shallow depths, sur- face ranges Will be shortened and, conjointly with sea States greater than 1, reverberation bursts may seriously obstruct target recognition. In addition to. shallow positive temperature gra- dients, very- sharp salinity gradients, both vertical and /horizontal, associated with ice-melt regions ef- fectively decrease surface ranges. PAGE 22-46 Despite the poor reliability of sonar predictions in the regions dominated by ice, operational use of sonar for navigation appears both feasible and highly desirable. Operation HIGHJUMP reported sonar superior to radar during periods of low vis- ibility. ,Bergy bits and growlers were contacted with 100% recognition at ranges from 500 to 1,800 yards with supersonic sonar, and icebergs at 4,000 yards. Ranges of such magnitude, however, can- not be obtained on submarines or even on larger surface ships, as their target strength is apprecia- bly less than that of large ice objects. FIGURE 22-36 gives maximum echo ranges for high-frequency sonar on submarines surfaced or at periscope depth. Ranges on ice targets may be as much as 300% greater, dependent on size. The range chart is intended to supplement the presentation of per- cent probability of ideal echo ranging conditions (FIGURE 22-35) for operational use, and is con- sidered more accurate wherever ice may prevail. In computing the given ranges, sea state was dis- regarded, since seas are effectively damped by ice; the parameters considered were layer depth, target strength, water temperature, spherical spreading, and the average figure of merit for destroyers at 15 knots equipped with QHB. Ambient noise is very low in ice areas where seas are minimal. Although the noise level in- creases farther north, it is generally of secondary CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? NAVY-JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL RELIABILITY DIAGRAM E-EXCELLENT F-FAIR G-GOOD P-POOR DEPTHS IN FEET ? AREAS USUALLY INACCESSIBLE FE:7,3 EXTREMELY HEAVY PACK ICE INDICATES INTERVAL OF MORE I-1-1-1-1 THAN 50 FEET 137t IZIPE Dr( ICCI?E 90?EAST SPE 70? FIGURE 22-34. AVERAGE LAYER DEPTH (FEET) , SUMMER importance to sonar operations in summer, when the depth of the mixed 'layer is the limiting factor. However, winds of force 8 to 12 occur between 5% and 10% of the time, and during storms. echo ranging is restricted primarily by high noise and quenching. The high incidence of sonic mammals (whales and seals) in the Area may occasion false echoes. A distinct doppler associated with whales serves to distinguish? them from ice targets. How- ever, good echoes, persistent and without. doppler, are produced by blow wakes, which also can cause complete quenching if proximal. Whale concen- trations are greatest between 40?W. and 100?E. in the Atlantic and Indian Oceans, and north of CONFIDENTIAL SUMMER Cape Adare (7) between 170?E. and 180? in the Pacific. Their southerly limits vary with the edge of the pack ice. Killer whales haunt the fringes of the pack where seals are numerous, particularly in the Weddell Sea. . 2) Layer Depth ? South of 60?S., the depth of the mixed layer in summer seldom exceeds 150 feet, and there are large regions where the layer is less than 100 feet deep (FIGURE 22-34)..These regions of least layer depth are apparently stable features of the Area.. They occur where the ther- mocline has been strengthened by cold outflow from the continental shelf sinking beneath com- paratively warmer water to the north, thus con- PAGE 22-4750X1 , Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAt NIS 69 NAVY - JANUARY 1956 RELIABILITY DIAGRAM A-EXCELLENT F-FAIR G-GOOD P-POOR S. AREAS USUALLY INACCESSIBLE EXTREMELY HEAVY PACK ICE wiwINOICATES INTERVAL OF, MORE THAN 10% 110?A 10rE STEAST ALPE lYE EYE FIGURE 22-35. PERCENT PROBABILITY OF IDEAL ECHO RANGING CONDITIONS, SUMMER fining the effects of insolation to a shallow layer. Accordingly, slightly warmer surface water should be- associated with least layer depths. (The con- tour interval masks this relationship on the surface temperature chart, FIGURE 22-12.) The areas of shallowest layers also coincide almost exactly with the regions of greatest storm intensity. In the western part of the Ross Sea, and in the Weddell and Bellingshausen Seas, isothermal water extends to more than 450 feet at all times. First evidences of the seasonal thermocline nor- mally appear in November or December, when layer depths of 20 to 40 feet are common; with continued surface heating in summer, the thermal 'gradient PAGE 22-48 SUMMFR becomes stronger. In mid-March or as late as mid-April, increasingly strong winds together with waning sunlight weaken the thermocline, and the layer deepens to about 300 to 350 feet. In winter, no negative temperature gradient is present at any depth less than 450 feet? south of the Antarctic Convergence. 3) Echo Ranging ? FIGURE 22-35 gives the percent probability of ideal echo ranging con- ditioni'for the Area in summer. The depth of the mixed layer is the primary factor limiting ranges. However, in the northwestern Weddell Sea and.the central Ross Sea, semipermanent lows are of great importance: The prevailing easterlies are pre- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY ? JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL RELIABILITY DIAGRAM E-EXCELLENT F-FAIR G-GOOD P-POOR AREAS USUALLY INACCESSIBLE EXTREMELY HEAVY PACK ICE INDICATES INTERVAL OF MORE LU-U-I THAN 200 YARDS - - 100-FATHOM CONTOUR IO 120?C IIOE E 9VEAST EOE ME frE SUMMER FIGURE 22-36. MAXIMUM SURFACE ECHO RANGES (YARDS) ON SUBMARINE WITH 25.5-KILOCYCLE SONAR (QHBa) dominantly light to moderate in summer, and al- though local gravity winds cause storms of great intensity, their effects seldom extend beyond 15 miles to sea. Conditions average about 30% ideal in the greater part of the Area, being slightly better than average in the Indian Ocean and poorer in the Pacific. Very sharp transitions from poor to ex- cellent echo ranging conditions occur in the Wed- dell and Bellingshausen Seas, and in a large coastal region extending from Little America (17) to Cape Dart (22) . In MacKenzie Bay (2) and the Davis Sea (3), conditions are poorer but average about 50% ideal or better. Where conditions are least CONFIDENTIAL favorable (less than 20% ideal) , as in the north- western Weddell Sea and the cential Ross Sea, the semipermanent lows limit improvement. Echo ranging conditions probably are best in November, when the layer is still deep and the fre- quency of high winds averages around 5%, 'lowest for the year. Observations from the region south of South Georgia and the Ross Sea support this inference, but data are not sufficient to present full areal charts for the month. By late April, despite isothermal layers to 350 feet or more, echo ranging will be hampered considerably by quench- ing and ambient noise, since the percentage of winds of force 8 to 12 approaches an annual maxi- PAGE 22-49 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 - Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 mum, and low sea states in open water are in- frequent. So little of the Area is ice free in winter that echo ranging has not been considered for that season. It is expected, however, that the average. percent probabilities of ideal echo ranging condi- tions will be slightly better in all other seasons than in summer, although it is doubtful that they exceed 40% of ideal in the Area as a whole. (2) So far ?The region south of the Ant- arctic Convergence is characterized by a shallow sound channel which is the result of the summer thermocline. Autumn cooling and high winds de- stroy the thermocline; accordingly, no sound chan- nel exists during the greater part of the year. No deep sound channel is found south of the convergence. The shallow seasonal channel in the Area may be continuous with the permanent deep sound channel to the north, depending on the structural variability- of the convergence itself. Continuity is more probable in the Atlantic Ocean where the northward slope of the convergence is generally more gentle than in the Pacific or Indian Oceans where the slope is steeper. Because a con- tinuous channel is provisional, FIGURE 22-70 in- cludes only the depths of the seasonal channel south of the convergence and the southern limits of the permanent channel where known. In general, the channel shoals from a depth of about 400 feet south of the convergence to about 150 feet near the Antarctic continent, the axial velocity decreasing from approximately 4,770 feet per second at the convergence to about 4,715 ft./sec. near the continent. Very close to shore, and in the Ross and Weddell Seas, the , channel axis deepens slightly and the minimum velocity increases to 4,725 ft./sec. Channel depth and axial velocity are directly related: shallowest depths and least velocities occur together, as do greatest depths and highest velocities. The depth of the sound channel in summer together with the positions of the vertical? sections of sound velocity is shown in FIGURE 22-70. Minor but definite longitudinal variation occurs in the depth and velocity of the sound channel in this Area. The variation depends primarily upon the quantity of colder or warmer water, relative to the mean, present in or introduced into the locale under consideration. For example, the effect of cold Weddell Sea Water on the velocity structure of the Atlantic Ocean south of the convergence during summer is shown by vertical section A of FIGURE 22-70. The maximum channel depth (350 feet) and axial velocity (4,746 ft./sec.) are found at the northern- most station of this section, while at 61?S., the channel shoals rapidly to 200 feet and velocity decreases to a minimum of 4,712 ft./sec., owing to PAGE 22-50 NAVY - JANUARY 1956 the introduction of Weddell Sea Water. South of this latitude, the velocity increases somewhat, to 4,717 ft./sec. near the continent. In contrast to this cold-water section, vertical section B, also south of the convergence but in the Indian Ocean, shows the effect of warmer water on the channel structure. From north to south, the sound channel depth varies from 600 to '300 feet, while the axial velocity decreases from 4,768 to 4,717 ft./sec., never attaining the minimum of the cold water section. Where the convergence closely approaches: the Antarctic continent, the resultant effect on chan- nel depth and axial velocity can be inferred from the South Pacific ? Ross Sea vertical section (C) . North of the convergence, channel depths of the order of 1,000 feet are found, with axial velocities greater than 4,800 ft./sec., while to the south the channel depth is 200 feet and the axial velocity 4,738 ft./sec. Stations on either side of the con- vergence indicate a transitional channel structure with an average depth of 300 feet and velocity of 4,755 ft./sec. Both depth and velocity diminish southward to 150 feet and 4,720 ft./sec., respec- tively, at the seaward limit of the Ross Sea. In the Ross Sea, the channel deepens to 250 feet and velocity increases to a constant value of 4,725 ft./sec. A parallel situation exists in the Weddell Sea. The effects associated with the convergence are also apparent in the Drake Passage ? Bellings- hausen Sea vertical section (D) . North of the con- vergence in Drake Passage, a 400-foot sound chan- nel with velocities greater than 4,800 ft./sec. is found. To the south are the typical channel depths of 300 to 150 feet and velocities from 4,727 to 4,720 ft./sec., decreasing southward. Travers- ing the convergence the channel averages 350 feet in depth with ?an axial velocity of about 4,775 ft./sec. FIGURE 22-70, supplementing vertical section C, shows detailed velocity structure in the 'Ross Sea. The complexity of the structure reflects the in- trusion at depth of the warmer water transported by the East Wind Drift. Entering the Ross Sea along its eastern coast, this warmer water is as- similated rapidly, as is indicated by the decrease in velocity from 4,757 to 4,732 ft./sec. at 600 feet. High-salinity pockets at depth further complicate the picture. The combined effects of the seasonal thermocline, warm water intrusion, and high salin- ities result in a conglomeration of sound channels, ordinarily disconnected and highly transitional. In general, velocities south of the convergence average 50 ft./sec. less than velocities to the north. This anomalous situation will be important to depth determinations by echo sounders, which are cali- brated for an average sound velocity of 4,800 ft./sec. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY JANUARY 1956 MILITARY GEOGRAPHY The seasonal thermocline, and consequently the sound channel, are destroyed by cooling of the sur- face water and mixing by high winds early in autumn. Following this, and throughout most of the year, the greater part of the Area is covered by sea ice, so that no thermocline or channel de- velops until the ice breakup and initial warming in late spring. 6. Geology a. STRUCTURE ? The outline of the Antarctic *continent is roughly defined by the Antarctic Circle. Other than the deep indentations of the Ross and Weddell Seas, the only break in a nearly circular Outline is the Palmer Peninsula, which trends into a submarine and insular ridge extending as the Scotia Arc toward South America. The Antarctic has both a radial and a peripheral arrangement of marine structural features, as will be seen from FIGURE 22-71. Surrounding the con- tinent is a peripheral zone of deep oceanic basins, and beyond this, 300 to 960 miles north of the Antarctic continent, midway between it and the other continents of the Southern Hemisphere, there is a ring of suboceanic ridges and rises. In con- trast to these is the almost meridional orientation of structures such as Macquarie Rise and the Palmer Peninsula. A significant feature of the Antarctic continent is its great elevation: its average height above sea level is 6,000 feet, compared with 2,000 feet for the average height of all other continents. In this respect the two polar regions of the earth are in direct contrast. Within the Arctic Circle there is a relatively thin, permanently frozen sheet of sea ice overlying a deep oceanic basin that exceeds 2,000 fathoms in depth, whereas within the Ant- arctic Circle there is a land mass capped by an immense steep-sided ice plateau estimated at 8,000 to 10,000 feet in elevation. The continent is divided roughly into eastern and western portions by a depression extending between the Weddell Sea and the Ross Sea. Very little is known about the rocks underlying the ice in the interior of the great ice plateau of the eastern section, but it is thought that they may consist essentially of horizontal rocks overlying a pre-Cambrian complex. The plateau is bordered, on the periphery between 20?W. and 110?E., by a series of mountain ranges with peaks as high as 14,000 feet. The coastal area between 110?E. and 155?E. has peaks to 6,000 feet in height, and there is a mountainous area of unknown elevation in the region 72?S. to 78?S. and 110?E. to 140?E. The greatest mountain range in eastern Ant- arctica extends southward from Cape Adare (7) along the western side of the Ross Sea, passes to the northwest of the South Pole in the 180? to CONFIDENTIAL CONFIDENTIAL 90?W. quadrant, and is thought then to continue toward the Weddell Sea. This great range has been carved from a horst, 1,500 miles long and more than 100 miles wide, composed of a series of block-fault mountain's (FIGURE 22-37) . These mountains prevent the ice from spilling over into the depressed areas separating the eastern and western portions of Antarctica. At right angles to its main trend, however, the horst is cut by small grabens which afford exits for a small portion of the ice of the plateau. For the most part, this horst is composed of flat-lying sedimentary rocks which have been intruded by igneous materials. Volcanoes are associated with the horst faults. The_ depression extending from the Ross Sea to the Weddell Sea has been described as a graben or a downwarped area. It is still conjectural as to how much of this region lies below sea level, but it is generally conceded that the Ross and the Weddell Seas are not joined by a strait dividing Antarctica into two subcontinents. The western sector of Antarctica and the ad- jacent Scotia Arc contain two principal structural zones: the Cordilleran Belt and the Platform Belt. The Cordilleran or Alpide Fold Belt comprises Scotia Ridge and the west side of the Palmer Peninsula, and probably extends into Marie Byrd Land. This belt is composed of a multiple chain of folds consisting of Mesozoic and Paleozoic geo- synclinal sediments intruded by extensive gran- odiorite and gabbro rocks. Recent volcanbes are associated with this belt. The Platform Belt, which comprises the east side of the Palmer Peninsula and probably extends to Marie Byrd Land, contains late Mesozoic and Ter- tiary sediments which are slightly folded, but locally faulted and cut by plateau basalts of Ter- tiary Age. No active or Recent volcanoes are found in this belt. - Generally, it is accepted that the islands of the Scotia Arc and the Palmer Peninsula are related structurally to the Andes. However the relation- ship between the structures of Antarctica and those of New Zealand, Tasmania, and Australia is con- j ectural. b. BATHYMETRY (1) General ?The nearly circular Ant- arctic continent is bounded by peripheral and radial features (FIGURE 22-71) . The basins are periph- eral in nature and are separated by radial sub- marine ridges and rises that point like connecting links toward the other continents. Beyond the ring of deep-sea basins, there is a second peripheral ring of rises. (2) Continental and island shelves ?The continental shelf around Antarctica is the deepest in the world, the break in slope occurring at depths PAGE 22-E50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY ? JANUARY 1956 130?W 120?W 110'W 100?W 94/WEST 80?W 70?W 133?W .50"W 140. \ ,O.r;... ?-?,14,. ,. . .... ..... 40? w --..... / \ \ \ \ /150? S'.'../. 1 ./ 4,..c.. ? I, tk 70? \ 30. al N \ ? .? ? - -1 '"""fl -""fl' 4.4?.4',,,, 7. ?'''' , ? .....-- - E-7 ISO? V __170? ,,, ......., VP ..,706.5,,,t g . a I70. i ? iii,'"iiiigle? 0111;15? A'NTARCTICA Z ,.. '4 0 .N ? o 4. sr 10? E IGO? VIII e t e .4. 150?' ? LEGEND IF:71 HORST . I I GRABEN OR DOWNFOLD -- ?TREND OF THE SCOTIA 1 40? 1. ARC-PALMER FOLD -- AXES OF FOLDS AND/OR TRENRANGESDS OF MOUNTAIN FAULTS \ 40. E \ / 120'E 110?E 100?E STEAST BEN 70?E 40?E 50?E FIGURE 22-37. STRUCTURAL TRENDS between 230 and 280 fathoms (FIGURE 22-72) . The shelf varies in width from less than 20 to about 300 miles. It appears to be widest in the Ross Sea and the Weddell Sea regions and narrowest off certain parts of eastern Antarctica. Two broad embayments, the Ross Sea and Weddell Sea, are not deep gulfs but shelf seas which indent the coast 700 miles and 300 miles, respectively, from the outer edge of the continental shelf. Toward its outer edge, the shelf rises locally in a series of elongate terminal moraines which appear frequently and seem to outline the former maximum extension of the icecap. These mounds on the sea floor fre- quently are farther than '100 miles from the real PAGE 22-52 land front and are hundreds of feet high. Basins appear in various places on the shelf; some of these reach depths exceeding 600 fathoms. These depressions, if actual and not due to faulty sound- ings, probably are a result of glaciation. The oceanic island shelves are generally, very narrow, with the shelf edge located at 100 fathoms or less. South Georgia and the South Orkney Islands are exceptions, with the shelf edge at ap-' proximately 145 fathoms and 200 fathoms or more, respectively. The reason for this difference is not evident, although the South Orkney Islands appear to follow the deep trend set by the continental shelf along the Palmer Peninsula. ' CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY - JANUARY 1956 MILITARY GEOGRAPHY In contrast to the deep shelf of the Antarctic continent, the shelf edge along the southern tip of South America lies near 100 fathoms or slightly shoaler. Off eastern South America, it is wide and quite irregular, particularly in the vicinity of the Falkland Islands, where it is more than 400 miles wide. At Isla de los Estados (33) it narrows to less than 10 miles, broadens westward to 60 miles, and again narrows northward along the west coast. of the continent. This west coast is a highly glaciated region with a very narrow and irregular shelf, which is cut into short segments by deep fiords, some of which are almost 1,000 fathoms deep. Discussion of the bathymetric characteristics of other portions of the Antarctic periphery will be found in NIS 104-VII, 106-111, 106-11, and 105-XII. (3) Continental and island slopes ? Profiles of the continental slope of Antarctica show it to be relatively smooth and gentle, particularly in the Indian Ocean portion. Here it has a concave form with gradients ranging from 2? near the top to about I/4? at the bottom where the slope fades into the abyssal sea floor 150 miles from the con- tinent. Some irregularities occur even here, with indications of an occasional submarine canyon and seamount or seaknoll. In other sectors of the con- tinental slope around Antarctica, numerous sea- mounts and indications of submarine canyons are to be found. West of South America the gradient averages about 6?, but the slope is quite irregular. East of South America the continental slope is quite steep but is broken by a double ridge that extends east from the southern tip of the continent. The island slopes are generally much steeper than the continental slopes in this Area. West of the South Sandwich Islands the gradient is about 8? to the 1,500-fathom curve; there it becomes much more gentle. On the east and north sides of these islands, the slope descends into the South Sand- wich Trench with a gradient of about 6? to the 2,000-fathom curve, where it steepens to about 9? and continues to the bottom of the trench. A small terrace occurs at about 1,000 fathoms on this slope, but it is not evident to the south and west of the islands. The island slopes are quite regular and unbroken except for the canyons off South Georgia. (4) Submarine canyons ?The submarine canyons off the coast of Antarctica have not been identified or delineated accurately. Their very existence is subject to speculation. The indica- tions of these features may be due to difficulties encountered in navigating and piloting through broken ?ice fields and along unsurveyed coasts where numerous course changes are required. If canyons are actually present, they may display either the V-shaped cross section typical of sub- CONFIDENTIAL CONFIDENTIAL marine canyons, or the U-shaped cross section typical of glaciated fiords. In the latter type there may be shoaling at the outer limits because of terminal moraine deposits which mark the sea- ward limit of the glacier. George VI Sound (26) is considered to be a structurally controlled sub- marine canyon. Indications of several submarine canyons may be found off the west and south coasts of South America. The only submarine ? canyons known to exist off the islands of the Area are on the north and south sides of South Georgia. (5) Seamounts and seaknolls ? Seamounts and seaknolls are found abundantly throughout the Area; they appear to be most common along the crests of the ridges and rises (FIGURE 22-71) . A lesser number are found on the continental slope and scattered throughout the various basins. Banzare, Gribb, Iselin, Barth, and Maud Sea- mounts all lie upon the radial structures that extend from the continent; Spiess Seamount is on the outer peripheral ring of rises surrounding the continent. The Pacific - Antarctic Ridge ("Easter Island Cordillera") has a great num- ber of seamounts and seaknolls concentrated just north and east of Balleny Basin. Another con- centration of these features is found on the rise extending into the Pacific - Antarctic Basin ("Bel- lingshausen Basin") from Antarctica in the vicin- ity of the Amundsen Sea (23) . The seamounts shown in the basins commonly occur along ex- ' tensions of ridges and rises or upon a slight rise of the ocean floor. (6) Ridges, rises, and plateaus ? The ridges and rises in the Area tend to form two intersecting patterns: the first is a radial pattern pointing from Antarctica in a northerly direction; the sec- ond is a peripheral pattern at a distance varying from 300 to 900 miles from the continent. The best-defined ridge in the Area is the Scotia Ridge (FIGURE 22-71) . This arcuate ridge which is steep, high, and sharp extends eastward from the tip of South America through Burdwood Plateau, Shag Rocks (35), South Georgia, and Clerke Rocks (36) to the South Sandwich Islands. Here the ridge turns south along the islands, then west- ward through the South Orkney and South Shet- land Islands to the Palmer Peninsula. Burdwood Plateau, near the South American terminus of this complex sigmoid ridge, is shoaler than 100 fathoms for a distance of over 200 miles. In this vicinity and eastward to Shag Rocks the arc appears to be double, being divided by a broad trough. The northern ridge of the arc includes the Falkland Islands and extends eastward to a point about 100 miles due north of Shag Rocks. The southern ridge includes Burdwood Plateau and extends the length of the arc. .50X1 PAGE DeclassifiedDeclassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 The Central Indian Rise continues south of the ridge through Bangore and Gribb Seamounts and provides a deep sill between the basins on either side. It is surmounted by the Kerguelen - Gaussberg Ridge, which does not extend south to Antarctica. Macquarie Rise, extending south from Australia, is also surmounted by a ridge (South Tasmanian Ridge) that does not reach Antarctica. The narrowest rise in the Area is the Southwestern Auckland Rise, which extends south from the New Zealand Plateau. Also extending south from this plateau is the Campbell Rise, which terminates in Emerald Basin. The Pacific-Ant- arctic Ridge as contoured on FIGURE 22-71 appears to be rather simple in this Area, probably because of the sparseness of available data. It is appar- ently a system of submarine mountain ranges comparable to some of the large cordilleras on the continents. Soundings reveal a flat bottom on either side with no indication of a foredeep, and a general absence of concave sides. About 80 miles north of the ridge an unsubstantiated escarpment has been reported; this feature rises from a depth of nearly 3,000 fathoms to a sharp peak at 1,180 fathoms and has the appearance of a north-facing tilted fault block. The fault face has a straight profile with a declivity of 63?. The gentler south slope also is straight, but with a gradient of only 11?. This asymmetrical scarp appears to have a foredeep. Slight, almost imperceptible rises separate the Pacific - Antarctic Basin from West Scotia Basin, and West Scotia Basin from East Scotia Basin. Although on FIGURES 22-71 and 22-72 South Geor- gia Rise appears to be a part of the Atlantic-Indian Rise, actually these are two separate features which merge near Spiess Seamount in a vast uplift of the ocean floor which involves several other ridges and rises north of the Area. The South Madagascar Ridge is an ill-defined ridge which, if accurately contoured, is a borderline feature bearing resemblance to both ridge and rise, but lack of data makes it impossible-to resolve the various possibilities of its structural appear- ance. A submarine spur extending north from Riiser-Larsen Peninsula (1) has been reported to be an escarpment of considerable magnitude extending 300 miles from Antarctica. The escarp- ment has a 44? gradient on the east side, dropping from 1,100 fathoms to at least 2,700 fathoms with a suggestion of a minor foredeep. (7) Trenches and troughs ? The only trench in this Area is the South Sandwich Trench, which is also the only trench in the South Atlantic Ocean. This trench lies parallel to that portion of the Scotia Ridge which is .in the vicinity of the South Sandwich Islands. Arcuate in form, it has a recorded depth of 4,518 fathoms. It is PAGE 22-54 NAVY-JANUARY 1956 part of the cordilleran belt which is thought to extend from the Andes of South America through the Scotia Ridge to Antarctica. The southern extent of the trench is questionable because of the paucity of data. The northern limit appears to lie on the slope of the South Georgia Rise, but it may be related genetically to the wide and relatively shoal trough lying between the north- ern and southern ridges of the Scotia Ridge. A small terrace on the landward side occurs at about 1,000 fathoms on this slope, but it is not repeated on the seaward side of the trench. A number of glacial troughs are found on the west coast of South America. These troughs ex- tend into the numerous fiords along the coast, and depths in excess of 600 fathoms are to be found far inland. The submarine canyons pre- viously mentioned on the coast of Antarctica may be similar to these features. (8) Basins ? Profiles taken with echo sounders aboard ships crossing the peripheral basins show them to be relatively smooth and featureless. However, the continuity of the basins is interrupted by ridges and rises as well as by a number of seamounts. The basins as shown MI FIGURE 22-71 are elongated in an east - west direction, forming an almost continuous ring around Antarctica. Many of the sills separating the basins are insignificant in relief and, in some cases, poorly defined. The major basins such as the Southwestern Pacific, Bellingshausen, Atlan- tic - Indian Antarctic (or "Valdivia") , and Indian - Antarctic Basins have been sounded very sparsely, but the average depth appears to be just over 2,500 fathoms. In only a few places do the depths reach 3,000 fathoms. A number of small basins are found on the con- tinental shelf of Antarctica. These basins have a small lateral extent, but attain depths which ex- ceed 600 fathoms. C. BOTTOM SEDIMENTS - FIGURE 22-73 illus- trates the bottom sediment pattern in the sampled portions of the Antarctic region. In general, near- shore information is extremely limited, being con- fined principally to locations visited by explora- tory and scientific expeditions. Much of the data has been obtained by ships caught in the pack ice. Areas of easy accessibility, such as the Palmer Peninsula and the sector southward from New Zealand, have been given the most attention. Approximately 50% of the bottom sediment data shown on FIGURE 22-73 were extracted from re- ports of scientific expeditions which explored small restricted regions. The remainder of the data was obtained from nautical charts. More detailed information is available but cannot be shown on a chart of this scale. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY - JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 140. 150. 160. I7V 180. 17CP 150? I r I10W 120 110.15' 100?W 90. WEST 80W 70W 0* 50. 7 20' IV , Ie. v? - 41). E ? ? 5060 ---.... 0 . . .1.'"1:kvfer>?...--- I. '',?ro,,,, -3?....-.- \ , , ci ? 50 .,, _ . 4, r..., /1---------,.....,, A ' . .6. ,.....A ITL '?' 1,,..0....i. .000 .i 6o 2.: 4?? 00 9.Te0 ? . X' 1iiiSiiiii .t- J706 nft60 1 ' 50. .3-"?0-,a ,451.0'.t..... M. .6100''''711'? ? . / t ... ..., a .ie i ,i. 1 ,1 N ..4PA, 1 9'. ,,,, 7 I ? ; 4Idir,f / I . . . ./. ?0.0NT 4. ...._ . 7 0 . i '6 Is 1. , o TIC? NI N AR'C ....------e ''"I: .,, ,,?, r, ? :a,q,. /,-", , ,./. . 4.?/,/,/ -,,?, ? 0, ? ? , , ---.....:--,-,....-.?__ - , ...e / r , 9 .- ? 8 e cs'A . ? 6? , '."':?, .... \ i ? ? . , ,, OBSERVED GRAVITY 50-MILLIGAL INTERVAL . DASHED LINES INDICATE SPARSE DATA 130.E 12CP E HO. E . . 100E 90. EAST , 80. 5 70? E . 60* E - WE FIGURE 22-38. OBSERVED GRAVITY Dredge samples taken in the Weddell and Scotia Seas indicate that bottom sediments in this sector may contain a higher sand and gravel fraction than is shown on FIGURE 22-73. This may be true in other sectors as well. Data obtained from detailed charts of specific localities indicate that large rock areas exist in most of the nearshore and shallow water sectors. d. GEOPHYSICS (1) Gravity ?Gravity data for the Area are very sparse. The contours shown (FIGURES 22-38 and 22-39) from Auckland Island to the Adelie Coast (5) are based on values interpolated CONFIDENTIAL from a single line of six observations. Except foi the region off South America, data are insuffi- cient to interpret the gravity field. No attempt is made to correlate available data ? with the geology. . (2) Seismicity (a) EARTHQUAKES ? FIGURE 22-40 shows the locations of the epicenters of 186 recorded shocks as given in Source 54, and 14 additional" shocks listed in Source 154. The scale of this figure is such that a symbO1 may represent more than one epicenter. PAGE 22-5E50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY ?JANUARY 1956 130W 120. W 110?W . 100? W 90. WEST OW 70?W 60?W 50?W ?1;f0 ? 4+25 i?yttlit2h44 NV . 4CA / -50 s '31 0 Ai 3ir W cor.mr11V-? / :? .. . 'Fr i s \ __, s 4 ; ? ' 170? . ., m 4 La 180. 7V 80? I OA ? 50? 0. 0 N 1 . ' 1 -...T ? ,. /L , ? ? ,;:., , o 'NT AR,C TIC A 170? . . ' r )(\''''O',0 / 0 42 K 1 70. _ % 150? WA FREE AIR GRAVITY ANOMALIES 25-MILLIGAL INTERVAL DASHED LINES INDICATE SPARSE DATA 14 V ...,_ 1 / 130?E 120?E - I IV E 100?E SO? EAST 80E . nr( ' WC 50?E FIGURE 22-39. FREE AIR GRAVITY ANOMALIES The scarcity of known epicenters on the Ant- arctic continent may be due to a lack of adequate recording stations rather than to the infrequency of seismic activity. While this scarcity of reported activity may indicate that the expected shocks in the continental area would be of low magni- tude, it should be. noted that a low-magnitude earthquake occurring at shallow depths (0-60 kilometers) may be more destructive in the vicinity of the epicenter than a stronger but deeper shock. All the shocks in the Area listed in Source 54 occurred at shallow depths, -with the exception PAGE 22-56 of 5 shocks in the vicinity of the South Sandwich Islands. The following tabulation shows earthquake dis- tribution by class for the 4 quadrants of the Area. This list probably contains the majority of Class A, B, and C shocks which have occurred in the Area during the period covered (1904-1952). It does not reflect all of the innumerable minor unreported shocks (Class D and lower) which undoubtedly have occurred in the Area during this period. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY?JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 14V w 150. w IS. ISV UO? 19r . ..., RV I 30. W 12FW II V W 10V W 90. WEST Dry; TOW 60. W SOW 40. 10? o? r 60. 0 . oo a o 0 . o 0 al I 70 I i ..r i ,Pnti,1,-4 ."(,,,,,)? sr V . MON AlAtt. 6" `?? o o 0 0 0 o o, 0 .3 0, 00o i 0 o 4,10 ' o4 '? 2- - - -fi''......' ''''''.', , i k.....%, < C..i..k" .. 704 . 000 .0 0 ? 0 0 0 50 70. ? . 4--..? ` \ J -. ,..` -') ?H?G?'"/ Ve. w ,. .1:4,"?,,, ' ' - - Ir 1 . 24 1T-A R C T I CA .. e o t? o 0 0 ? o 00 p, %20: 046 ? 0 0 0 0 o? 0 o 0'0 0 00 ...i ,.., ? ft.ic2. ' , R , , . . ?........-..----- 0 00 0 0 o /7) 4 i, 0 ? a \ l? * . .2 .., o . NIP 0 p' o 0 0 0 0? 0 0 0 ' 0 o LEGEND SYMBOL INDICATES LOCATION AND DEPTH OF EPICENTER AND STRONGEST SHOCK THAT OCCURRED THERE. _EPICENTER AND DEPTH CLASS MAGNITUDE' DESTRUCTION (0-60 Km.) (70-300 Km.) 6 6 A 7.75 and above Major earthquake 0 0 B 7.0 to 7.7 Lower limit of major earthquake 0 0 C 6.0 to 6.9 Destruction over .a restricted area 0 . 0 1) 5.3 to 5.9 Locally destructive 0 SHOCKS FOR WHICH NO DATA ARE AVAILABLE AS TO CLASS OR DEPTH ? Logarithm of the maximum trace amplitude (expressed in thousandths of a millimeter) which would be registered on a standard seismometer at a distance of 100 kilometers from the epicenter. Brf . igrf IIVE 100q 50 5057 80* E ME 6VE 50. E QUADRANT A B CLASS C D 90?E. to 180? 2 6 58 18 90?W. to 180? 0 2 16 0 0? to 90?W. 1 23 43 0 0? to 90?E. . 1 0 15 1 Total 4 31 132 19 FIGURE 22-40. EARTHQUAKE EPICENTERS Unknown TOTAL 4 88 2 20 7 74 1 18 14 200 (b) VOLCANISM ? Thirteen active vol- canoes have been reported within the Area (FIG- URE 22-41) . Of these, 9 are situated along the Scotia Arc and associated structural features. Of those remaining, 3 are situated in the Balleny Islands and 1 on Ross Island (14). CONFIDENTIAL. With the exception of Mount Erebus (FIGURE 22-42) , which appears to be in a constant state of activity, no definite predictions can be given as to the probable nature or date of future activity of any of the volcanoes in the Antarctic. However, records of volcanic activity in other portions of the world indicate that the eruption of any of the quiescent volcanoes is possible. While a steam eruption would be of little importance, an ash fall may affect military operations because of its abrasive nature and effect on visibility. Further, since the ash from some volcanoes contains rela- tively high percentages of magnetic minerals, an PAGE 22-5'50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY ? JANUARY 1956 ?, 150? 170' 1E0 160' 150 AS i V 130'W 120?W 110'W 100'W 90? EST 80'W 70?W 60?W 50? 4r W W 20' r r e 0 LEGEND ACTIVE VOLCANOES INACTIVE OR EXTINCT VOLCANOES NUMBERED VOLCANOES ARE DESCRIBED IN FIGURE 22-42 ? --;L I C . n-,s ..43...? ip.. ...... ? / . 9 ?s ";04,--t. 44 ' 410k I. '' 0 11 / I A /4 ........ / ... ? ,... EV II I cpc9?.13 12 V 5?. . ? 4 7 . a . ..>>>------ ? k ,v . i;ok,'.7 - Ir S V C T IA 3 2 pr, ) 4 i. s ' !!..? ..1"-- . . A r..! T A R 'k Iil.0 4. A . .. i A ...---------j .) \ . 0 N ? , ?t' ..... 8. 70', ? .._, 177'E 127'E 110?E ? 100?E 90? EAST 80?E 70?E 60?E 50?E . FIGURE 22-41. VOLCANOES ash fall may change the magnetic characteristics of the bottom sediments; such changes could in- fluence magnetic sweep effectiveness and/or, the magnetic characteristics of mines placed on the bottom. (c) TSUNAMIS ? Although no tsunamis (seismic sea waves) have been recorded at Ant- arctica, phenomena of this type probably occur from time to time; however, no predictions of their magnitude can be given. Tsunamis generated by distant earthquakes and volcanic eruptions are most likely to occur along the Pacific coast; those generated by local earthquakes and/or volcanic, eruptions are most likely to occur in the vicinity PAGE 22-58 of the Palmer Peninsula, the Scotia Arc, the Wed- dell and Ross Seas, and eastern Wilkes Land. Tsunamis have been recorded in. the Antarctic periphery in regions such as the southern tips of Africa and South America and in the vicinity of Australia and Tasmania. (3) Magnetism (a) LOCAL MAGNETIC ANOMALIES ? With the exception of a single aeromagnetic survey and observations at two points, no detailed informa- tion is available on the local anomalies of the magnetic field on the Antarctic continent. Pos- sible high vertical or horizontal magnetic anoma- -CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY-JANUARY 1956 MILITARY GEOGRAPHY FIGURE 22-42. REPORTED VOLCANIC ACTIVITY CONFIDENTIAL LOCATION ON FIGURE 22-41 NA ME LATITUDE LONGITUDE ' REMARKS 1 Freeman Peak* 66?25'S. 162?23'E. Reported active by Balleny in 1839, has not been verified. 2 Buckle Island 66?48'S. 163?15'E. Balleny reported smoke from two craters 1839. The Southern Cross - reported smoke 1899. No activity reported by the Discovery 1904, or Discovery II 1936 and 1939. 3 Sturge Island 67?24'S. 164?15'E. Activity reported, but date and observer unknown. No activity noted by the Discovery in 1904. 4 Mount Erebus 77?35'S. 167?10'E. Almost continuous activity. Steam clouds, which rose 3,000 feet above summit, and fire at night noted in 1908 on 18, 21, 25, 30 June; 6, 15, 16, 17, 19, 27 July; 1, 25 August; 18 September. Ash and pumice reported 1912. 5 Sjovold Mountain*.. 69?12'S. 72?50'W. Thick black smoke reported by the Bouvet III 1931. No steam or smoke noted by the Thorsh,aven 1935. 6 New Island* 65?12'S. 72?12'W. Reported by Lutterfeld 1877. Existence highly doubtful. 7 Monte Burney 52?18'S. 73?24'W. Reported active 1910; no data available as to type of activity. 8 Mount Pond 62?56'S. 60?34'W. No date. Glacier contains layers of ash. Active fumaroles along the beach at Whalers Bay. 9 Bridgeman Island... 62?04'S. 56?40'W. Eruptions reported in 1.821 and 1839. Charcot landed 1909 and found evidence of recent activity. 10 Christensen Nuna- tak. 65?06'S. 59?34'W. Reported active by Larsen 1893. Nordenskjold found crater extinct in 1902. 11 12 Lindenberg Island... , Mount Darnley 64?55'S. 59?03'S. 59?42'W. 26?30'W. Larsen 1.893 reported thick black smoke. The ice melted for a con- siderable distance around the island. Ejected stones were observed on the ice. No activity noted by Nordenskjold in 1902. Sulfur flow reported in 1908. Lava flow reported 1936. 13 Zavodovski Island... 56?20'S. 27?34'W. Sulfur flow reported 1908. * Location and name not verified by U.S. Board on Geographic Names. lies (FIGURE 22-43) have been inferred from the magnetic character of the rocks near and on the surface. Local magnetic anomalies are of some military importance; for example, they are used in the setting of dip needle mines, and as a means for submarine evasion of the Magnetic Airborne Detector. The known geology of the Palmer Peninsula and the islands about it indicate igneous rock; hence, magnetic anomalies of 1,000 to 3,000 gammas probably occur. Near Little America, a sharp total-force magnetic anomaly of about 1,000 gammas was found at 79?35'S., 169?50'W. by aeromagnetic survey. Near Ross Island (14) at 77?51'01"S., 166?36'42"E., a horizontal anomaly of over 2,500 gammas was recorded during a magnetic survey by the British Discovery Expedition. - The Auckland Islands area contains several mag- netic anomalies. At 50?44'30"S., 166?08'24"E. there is a negative vertical anomaly of more than 1,000 gammas. At 50?48'30"S., 166?00'48"E. there is a large anomaly in declination of about 10?: the declination in this Auckland area is normally about 18?E. but the compass at this location reads about 7?50'E. Such a change from the normal declination would require a magnetic force per- CONFIDENTIAL pendicular to the magnetic meridian of about, - 1,500 gammas. (b) SHORT-DURATION MAGNETIC FLUCTUA- TIONS 7-- Large magnetic time variations usually Occur within and at the ,boundaries of the auroral zone. In such areas it is not unusual for magnetic time changes with rates as high as 1 to 2 gammas per second to occur. To show the regions over which such rates can be expected to occur, the zones of high auroral activity are illustrated in FIGURE 22-44. Quantitative data of short dura- tion fluctuations in this Area are rare. The few rapid-run magnetograrns available for the Ant- arctic are of too short a time period to evaluate statistically. (C) MAGNETIC CHANGES OF LONGER DURA- TIONS - FIGURE 22-45 shows tabularly magnetic changes of longer duration for the auroral zones delimited in FIGURE 22-44. The numbers in the body of the table show the number of days, weeks, .months, etc., which are expected to .elapse before the daily, weekly, monthly, etc., range of the component considered will exceed a certain mag- nitude. For example, for the H. component (rep- resenting horizontal intensity) the number 12 at the intersection of the day row and the 1,000 col- umn .shows that 12 days are expected to elapse before the daily range of the H component will exceed 1,000 gammas. PAGE 22-59 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY ? JANUARY 1956 130?W . 12VW 110?W . 100?W 90?WEST 730?W 70v ' saw 50?W ? II/C? 140? LEGEND n' /17 t:, Fr A5S0 ()..1K E2L Yo 0700 GELHars ANOMALIES IN l S 11K E LeT0 EXHIBIT ANOMALIES A . , .WItpo503,000GAvAS 40. ? KNOWN ANOMALIES 150. W ? - /) 70? 01 w - ...., P'? ,, . = \ g -? ?1`111111:14 y, s il q 0000 170? e - -.i allilillilt IV , 000 GAMMAS TOTAL INTENSITY . 4.. 11?1,111 ? . .???? f V ---1 -- 2500 GAMMAS HORIZONTAL INTENSITY \- ,i 1., ? ..,^ --O.' _. 1.2" 180. ----c ,,, 60. , ' 're /PI- 50. ii,V/;( i.. . / 71 -I 1 ' " " a AN . TAR.CTICA .n z w . 2 0? 170. "../ 1000 GAMMAS VERTICAL INTENSITY JR , it, 7 0 1500 GAMMAS DECLINATION \ ? c0 , r s 70. 7 15D? 1.? ? a 1 145. 2600 GAMMAS VERTICAL INTENSITY r ki? IIPP'' \ ? ? 135.E 127E 115.E IV E 90? EAST 60?( 70'E WE 5VE ? FIGURE 22-43. MAGNETIC ANOMALIES 7. Marine biology a. ATTACHMENT FOULING (1) General ?Fouling is the attachment and growth of sessile marine algae and invertebrate animals upon underwater ordnance and equipment. On ships' hulls this attachment can result in loss of speed and increased fuel consumption. It also may interfere with the normal operation of under- water ordnance such as antisubmarine nets, mines, and sonic devices. , Collections by various Antarctic expeditions point to a generally abundant and varied invertebrate fauna; however, little if any work has been done on PAGE 22-60 growth rates and periods of reproduction in rela- tion to various ecological factors of the Area. The only known specific fouling study was conducted for a one-year period at Heard Island. Algae, some of which may contribute to fouling, are discussed in topic 7, c. (2) Geographic variation ?The Area may be divided roughly into two regions, the subant- arctic and the Antarctic, where some differences in fouling characteristics are noted. (a) SUBANTARCIIC REGION ? This region includes the portion of South America and the islands between 40? and 60?S., with the exception CONFIDENTIAL 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? 'NAVY ? JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL FIGURE 22-44. SOUTHERN AURORAL ZONE ? FIGURE 22-45. MAGNETIC RANGES IN THE SOUTHERN AURORAL ZONE TIME PERIOD Magnitude (gammas) Magnitude (gammas) Magnitude (gammas) 200 500 1000 1500 200 500 1000 1500 200 500 1000 1500 Day 1 12 1 350 1 20 Week 2 17 4 1-month 1 30 1 3-month 1 30 15 200 6 6-month 1 8 2 Year 3 1 * Values in the graph i idicate expected average nui Ther of tine periods elapsing before ranges in horizontal intensity (H), Mag- netic declination (D) and vertical intensity (Z) will exceed the magnitudes indicated. CONFIDENTIAL ? PAGE 22-60X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL 'NIS 69 of the South Sandwich Islands. The degree of fouling in parts of this region has been estimated in other NIS's as generally slight, although it may range to moderate in many localities. In the study at Heard Island, only algae attached to the test panels. A number of organisms, nevertheless, are expected to be prominent in the fouling complex, and are present generally throughout the region. Mussels, algae, barnacles, tubeworms, hydroids, sponges, bryozoans, and tunicates may attach in that order of abundance. In the cold waters of this region the period of attachment probably is limited to one to three of the warmest months, February, March, and April. Where ice abrasion occurs, fouling cannot develop on exposed surfaces. (b) ANTARCTIC REGION ? Ice abrasion is probably the most important factor affecting foul- ing in this region. Where ice abrasion is absent or rare, fouling develops on suitable surfaces. Attach- ment probably occurs during the warmest part of the summer season, but growth of the attached organisms is believed to be slow. The following organisms may be expected to be present in de- scending order of abundance: bryozoans, sponges, algae, sea anemones, tunicates, hydroids, barnacles, and tubeworms. b. BORERS ? Gribbles (Limnoria), the most destructive of crustacean borers, are represented in the Area by a single known species Limnoria antarctica. This species is fairly common in such places as South Georgia, but no evidence of boring has ben recorded. Borer activity is expedted in some of the northern extremes of the Area, but no records are available. C. ALGAE (1) General? Large brown algae com- monly called kelp occur in the Area. At least five species are of such large size or occur in such abundance that they are considered important to military operations (FIGURE 22-46) . Macrocystis, the largest alga in the Area, commonly grows to depths of 150 feet in small to enormous fringing or offshore beds. The floating portions of these. plants form dense entangled masses on the water surface which may be impassable to small propeller- driven craft. Durvillea is a massive plant of wave- exposed shores. Its thick leathery blade may be broad or split into several strap-shaped sections. Lessonia, a treelike forth, may have a trunklike stem (stipe) as thick as a human thigh. It grows chiefly below the lowest tide level, where groves of these plants resemble submarine forests. Phyl- logigas is an inhabitant of the sublittoral zone to depths of over 100 feet. Desmarestia, another sub- littoral alga, covers many bottom areas with dense growths. Many other algae contribute to the littoral and sublittoral flora. PAGE 22-62 NAVY ? JANUARY 1956 The last three forms, when growing abundantly in their habitat, may interfere with wire drags and mechanical minesweep gear. Beds of the algae also may offer some concealment to minefields and may interfere with the placement and operation of listening devices. (2) Geographic distribution (a) SUBANTARCTIC 'REGION ? The greatest abundance of algae in the Area exists along the subantarctic coasts. Luxuriant growths of four of the large brown algae exist along the southern coasts of South America, and about the Falkland Islands. The subantarctic islands have generally abundant marine floras, although ice action has a limiting effect around some of the islands. (b) ANTARCTIC REGION ? Only one large kelp (Phyllogigas) is known from this region. On rock, cobble, or sand and shell bottoms, it grows within its depth range wherever ice abrasion is absent or rare. Under optimum conditions, it oc- curs in dense stands. This alga has been reported specifically from such widely separated localities as the South Orkney Islands, Palmer Peninsula, McMurdo Sound (11), and Commonwealth Bay (6). Its distribution probably is circumpolar. Desmare- stia is usually abundant in all suitable localities, usually extending to greater depths than Phyl- logigas. (3) Plankton? Several worldwide reports concerning blockage of ship intake lines by high concentrations of plankton are recorded. In the vicinity of Peter I Island (24 ) and in the Ross Sea region, the high concentration of diatoms and copepods caused the evaporators of the U.S.S. Atka to become clogged with a thick coating. This con- dition resulted in faulty operation of the evapora- tors, requiring frequent cleaning. (4) Sea grasses ?True seagrasses, such as Zostera, do not grow in the Area. d. BIOLUMINESCENCE (PHOSPHORESCENCE) (1) General? Antarctic waters are particu- larly rich in nutritive salts which well up into the cold surface layer enabling an abundance of plank- tonic organisms to flourish. The principal bio- luminescent animals included in this luxuriant plankton are those which produce a discrete spark- ing type of light, such as euphausiids, copepods, and ostracods. The euphausiids, or krill as they are known to the whalers, are the main source of food for whales and often occur in tremendous shoals numbering billions of individuals. Two other types of bioluminescent displays may be seen in this Area: the diffuse ball-like glows of jellyfish and tunicates, and the brilliant sheetlike luminescence caused by large shoals of protozoans. The first type often takes the form of separate CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY?JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL 130?W . 120?W 110?W 100?W 90?WEST 60?W 70"W 60'W 50'W 140? i9niiii W* te. 'k, 'k,' )? ' , , . fi'A I Fin- /A7 v) . A 4 ,1 ' 1 I i i\ \\ . '.41!. ? ' c....!..4, ."4, ,,.;,, ????? \ .. - ?? ??? ---." 4, MACROCYSTIS ' P. -- / \ N. TO 180 FEET LONG , ? 10? \ / 1 V LESSONIA A , ors17.10 \ I ..), TO 10 FEET LONG 16cr W ---.. 1 / .4'1". 1 - 1 ' .- ?-? / - - - ,. , ( , fi ? : / . / c '1 1 / W 1,1,0? ?.?....? DU RV1 L LEA ..... IIP r;... ' TO 30 FEET LONG ? 0 If ? ' N'tc..?.... . V OP _ ,,, 1 ROSS IC!, 5:111). 70. to go. 71:E,,,y,_ OP SP ',.' --f121' ,i'76. ????". ...... 1 , 11') l' A -1 ,,, , I ? (0). 170? AN TXR C TICA''....?.','.2 i . 7. I . / 0 ? r / ? q? , ? - 7 1 , . / PHYLLOGIGAS N TO 30 FEET LONG 1ST i ...... ...... 140? LINES REPRESENT OCCURRENCE ALONG r/...a ?-..' ?DESMAREST \ , A EV . ----.--'1,.._ COASTS ONLY, NOT SEAWARD (-)NATION Y...' TO 6 FEET LONG.? _ ? ? 130?E 120?E ' 110?E 100?E 93. \ , ? . \ / EAST ' 80t Opt OPE - SPE FIGURE 22-46. DISTRIBUTION OF KELP AND OTHER LARGE ALGAE flashes of light which glow brightly for a few seconds and fade out. However, if jellyfish or tunicates are sufficiently concentrated, a sizable area may be suffused by their luminescence. The sheetlike displays produced by protozoans may ex- tend for several miles along the sea surface. These phenomena are the result of some physical, chemical, or mechanical stimulus, such as surface wave action, internal waves, general turbulence, precipitation, salinity and temperature. changes, and movements of vessels and marine animals. However, bioluminescent displays of military im- portance would require large concentrations of luminous organisms. CONFIDENTIAL (2) Geographic distribution ?The distri- bution of bioluminescent organisms is indicated in FIGURE 22-47. They are generally, abundant south of the Antarctic Convergence, with the 'ex- ception of the eastern part of the Bellingshausen Sea (25), off the Palmer Peninsula, and about the South Shetland and South Orkney Islands. The zone of maximum abundance shown in FIGURE 22-47 roughly follows ?the Antarctic Divergence where upwelling of nutrient-laden water renders conditions especially favorable for the growth and reproduction of plankton. The southern boundary of this zone is the pack-ice edge. ?The rich Weddell Sea water is carried northward into the Scotia Sea, PAGE 22-6350X1 L. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 NAVY - JANUARY 1956 LEGEND MAXIMUM ABUNDANCE OF 'BIOLUMINESCENT ORGANISMS HIGH, INCIDENCE OF BIOLUMINESCENT, ORGANISMS MODERATE TO LOW NUMBERS .OF BIOLUMINESCENT OR OBSERVATIONS OF BIOLUMINESCENCE 70.1 60?E FIGURE 22-47. DISTRIBUTION AND RELATIVE ABUNDANCE OF BIOLUMINESCENT ORGANISMS AND RECORDS OF BIOLUMINESCENT DISPLAYS thus accounting for the dense plankton populations of the South Georgia and South Sandwich Islands whaling grounds. Bioluminescent displays are expected to be most common in the waters known to support large popu- lations of Plankton as shown in FIGURE 22-47; how- ever, local conditions may promote the rapid in- erease of plankton anywhere in the Area. The fact that it is a common phenomenon in these southern waters is brought out in FIGURE 22-47 by the relatively large number of positive observations reported by the few expeditions that have recorded such data. PAGE 22,64 (3) Seasonal variation ? Summer, particu- larly late in the season (February-March) , is the time of greatest organic activity in Antarctic waters. In mid-November, a marked increase in plankton occurs south of the Antarctic Con- vergence to the pack ice. Pelagic life continues to flourish until it reaches a maximum in late February or early March, the center of abundance moving south with the receding pack ice. Studies on the principal species of krill show that these luminescent crustaceans tend to Concentrate along the edge of the ,pack. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY - JANUARY 1956 MILITARY GEOGRAPHY Many bioluminescent organisms are present at the surface in reduced numbers through the winter, but most of the plankton descends to depths during the coldest months. e. DANGEROUS MARINE ANIMALS ? Dangerous marine animals in this Area are confined mainly to jellyfishes and killer whales. Jellyfishes, the only dangerous invertebrates in these southern waters, occur as far south as the icepack. Among the Antarctic coelenterates are certain members of the family Cyaneidae which are jellyfishes well known for the virulence of their sting. They usually are found in relatively shoal water. Killer whales are undoubtedly the most danger- ous., animals in this Area. These fierce mammals hunt in small packs preying on other warm-blooded animals in the sea. They have been observed at- tacking seals on ice floes by crashing against the under side of the floe to dump the seal into the water. A photographer with an early Antarctic expedition was attacked in this manner by a small group of killers. They came up under the ice on which he was standing, breaking it into fragments. He barely escaped death by leaping onto firmer ice. Killer whales roam these waters all year, being most numerous along the edge of the icepack and about the southern islands. f. HUMAN SURVIVAL IN WATER ? Owing to low surface water temperatures, survival time of im- mersed individuals in this Area is relatively short. Where water temperature ranges from 350 to 40? F. survival is less than 90 minutes and in less than 35? F. water, survival time is less than 45 minutes. These times are those which may be expected by individuals dressed in ordinary shipboard clothing and kept afloat by life jackets. Actual field experi- ments and laboratory tests have shown that struggling or swimming in cold water will increase survival time much more than merely clinging to wreckage or floating passively on life belts. g. SONIC MARINE ANIMALS (1) Sonic fishes ?None of the true Ant- arctic fishes, which include the nototheniids and a few other families, is known to possess sonic qualities. Therefore, no fish noise is expected south of the Antarctic Convergence. Limited interference caused by sonic fishes may be encountered in summer off the tip of South America and about the Falkland Islands. Here are found a few pelagic fishes with sound-producing characteristics, namely, herring, jacks, and some bottom fishes belonging to the cod and scorpionfish families. (2) Sonic mammals ? Whales, porpoises, and seals are common within the Area, and all are potential noise sources. Whale migration and movement habits are usually presented in the NIS; CONFIDENTIAL CONFIDENTIAL however, in this Section areawise monthly distribu- tion of the commercial species is the main presenta- tion. In general, this presentation is based on recorded movements of blue whales (Balaenoptera musculus), fin whales (Balaenoptera physalus), humpback whales (Megaptera nodosa), sei whales (Balaenoptera borealis), and sperm whales (Phys- eter catodon). In addition, right whales (Balaena australis), bottlenosed whales (Hyperoodon plani- Irons) , and little piked whales (Balaenoptera acuto- rostrata) occasionally are considered in the sta- tistics. The vast majority of the whales are present d ar- ing November through March. The few whales which remain in the Area during the remainder of the year are found in direct relation to the position of the pack-ice edge. Whales here are circumpolar in distribution, depending largely on the occurrence of krill (Euphausiids). In FIGURE 22-74, the aver- age monthly population densities are presented in the artificial areal breakdown of the Interna- tional Whaling Commission as limited by 50?S. lati- tude and the average monthly pack-ice position. Occurrence is presented both in numbers of whales expected during any specific month per 10,000 square nautical miles and as the number of square nautical miles per whale. Average densities range from 8 to 90 whales per 10,000 square nautical miles ' or one whale per 111 to 1,250 square nautical miles. Area I (70?W. to 160?W.) was closed to whaling for several recent years. Consequently, the only data are from the strip sampling of the U.S.S. Canisteo (1946-47) . These data show an average concentration of one whale per 34 square nautical miles of open water outside the pack, and trips into pack-ice leads showed one whale per 13 square nautical miles of open water. Only fin and little piked whales were considered in these data; there- fore, they cannot be compared directly to the sta- tistics of the catch. Whale movement during the summer months is concentrated- in lateral dispersal within 50 latitude adjacent to the pack ice. No set pattern has been discerned as yet for these dispersal movements. Approximately 22 species of lesser whales and porpoises have been recorded from the NIS 69 Area. When considered as a group, these animals are dis- tributed circumpolarly. The killer whale (Orcinus orca) is the most important of these, ranging along the pack around Antarctica where it feeds on other porpoises, seals, and penguins. Seals are circumpolar in relation to pack and fast ice in the Antarctic proper; however, they are not found in great concentrations. Weddell seals (Leptonychotes weddelli) are essentially animals of fast ice, utilizing breathing holes in the ice. They are also found in small numbers on many islands of the Area. The rare Ross seal (Ommatophoca PAGE 22-6550X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 . rossi), the leopard seal (Hydrurga leptonyx), and the crabeater seal (Lobodon carcinophagus) are animals of the pack ice. These are also found on ? many of the islands of the Area. The elephant seal (Mirounga leonina) is found principally within the subantarctic regions of the Area, particularly South Geofgia where the popu- lation is over 250,000. Elephant seals have also been reported along the northern fringe islands of Antarctica. h. DEEP SCATTERING LAYER (1) General?The term "deep scattering layer" (DSL) has been given to the phenomenon of a horizontally stratified sound scattering layer in NAVY - JANUARY 1956 the sea. ? The distinguishing characteristic of the layer is a diurnal vertical migration, usually of 100 fathoms or greater, descending during the morning and ascending during twilight hours. Generally, it is believed that the scattering is caused by living organisms such as plankton, squid, or fish. The layer trace as recorded on fathometers often has been misinterpreted as representing true bottom depth, and the term "phantom bottom" has been applied. (2) Geographic occurrence? DSL observa- tions in the Area are available from four ships. The tracks and a' single station where the layer was observed, together with the prevailing daytime depths of the layer, are illustrated in FIGURE 22-48. ',.,g?nn.....?...g r I3TW l20W 110?W 100?W 90? EST 90?W 70?W 60?W 50?W I Cr ? RICA .24 H. \ IT I W . T KA 19 u6 ...---? ........"--,......... U.S.S. ATKA (FEB. 195 ? 0 ? 200 5 ...sot] "4.?-? 1 30? W MO? r , i - A A IFEB.I? 55) ?BLE LAYER 170? 0.3 ? /9... 4,,s... ? ' _ ' -- ...: N. . `... - ..,---------------.1 0 .???? -11 4 711`.. ( ???,..- ^44l ,?, ..?-------- r / ? ??? .., J ? not Mit60 10. 170? 160? ''?;: ..,...... ,,s09-49" (:) () P ? P DISCOVERY MULTIPLE 27, 41 6, 4. ,A014 ? GO' .../ U.S.S. ATK2A7 . \ TI EC. 50) CHOES ...." AND 68 f - C 04 - ' 1? 1 t J.AN. 19 55)----77g ,...-? -1,97- P .?........---- N T AR ),... , / 4 \ . . ......, C TIC lir lip . -...... v., .2 / V/ .../ / A V / E 2EV ? US REND 0 (JAN.I947 .?.. 2 25 ........? .-... ?... .-- "-"".. ....- 60. LEGEND ? ? INDICATIONS OF DSL RARE OR ENTIRELY ABSENT U.S.S. HENDERSON 447) -.........---. CONTINUOUS OR ALMOST CONTINUOUS NO? E ? ? COMMANDANT C/A T 1JAN.19 9) Ilk 0 -.-- ..? --. DAYTIME DEVELOPMENT OF DSL NUMBERS INDICATE PREVAILING DAYTIME DEPTH OF DSL IN FATHOMS ? STATION LOCATION 4 E 130?E 2541 110?E 1 254 . 90? EAST 85E 75E 454 SO? E PAGE 22-66 FIGURE 22-48. TRACKS AND STATION WHERE DSL HAS BEEN OBSERVED CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? NAVY-JANUARY 1956 MILITARY GEOGRAPHY The southernmost observations of DSL were made by the U.S.S. Henderson and were the only ones reported by any ship navigating through or immediately adjacent to the icepack. It may be especially significant that the layer was neither recorded nor heard on the echo sounder of the U.S.S. Atka during its navigation around western Antarctica. Discrepancies exist regarding the latitudes at which the layer reportedly disappeared in the Antarctic region. Termination of the layer at about 56?S. (about 7? north of the Antarctic Convergence at that time) was recorded aboard the Atka. The Henderson recorded the temporary termination of the DSL when crossing the Antarctic Convergence (about 62?S.) , whereas the Comman- dant Charcot did not lose the layer trace until the limit of drifting pack ice was reached (about 64?S.) , almost 10? to the south of the convergence at that time. Reappearance of the layer was recorded at about 61?S. by the Commandant Charcot and at about 62?S. by the Atka when leaving Antarctic waters. Some correlation was noted between the depths of the multiple echoes detected by the R.R.S. Dis- covery -II and temperature layering as shown by bathythermograph traces. This ship also used lower frequency sound than the other ships (10 kilocycles instead of 18 or 24 kilocycles) . The possibility exists, therefore, that the sources of the echoes were of a different nature from those causing the deep scattering layer detected by the other ships. All known DSL observations in this Area have been made during the months December through March, since no ships reporting or recording the layer have navigated in Antarctic waters during the other months. On the basis of available ob- servational data, it is believed that detection of the deep scattering layer reasonably may be ex- pected in the circumpolar waters to approximately 60?S. during the period December through March, and possibly may occur there during the remainder of the year. In higher latitudes, it may be expected to be rare or entirely absent. C. Coastal Sector 1: Palmer Peninsula, South Orkney Islands, and South Shetland Islands 60?S. to 75?S.; 44?W. to 79?W. (FIGURE 22-76; USHO Chart 6639; B.A. Chart 1775) 1. General Coastal Sector 1 includes the Palmer Peninsula, South Orkney Islands, South Shetland Islands, and other islands off the coasts of the peninsula. The northern end of the Palmer Peninsula, which is the most northerly extremity of Antarctica, lies approximately 560 n. miles south of South Amer- ica. The peninsula is about 950 miles long and CONFIDENTIAL CONFIDENTIAL is bounded on the west by the Pacific Ocean, on the north by Drake Passage, and on the east by the Weddell Sea. The South Orkney Islands lie approximately 360 n. miles northeast of the penin- sula, and the South Shetland Islands lie about 60 n. miles north of the northeast part of the peninsula. Disregarding small coastal irregulari- ties, the coasts of Coastal Sector 1 total about 4,000 miles in length. Most of the west coast of the Palmer Peninsula is relatively ice free during at least a part of the summer; however, approaches to this coast are channelized by the many off-lying islands, islets, rocks, and shoals. Similar ice conditions prevail in the approaches to the South Orkney Islands and the South Shetland Islands during most of the summer months. Except at the northeast end the east coast of the Palmer Peninsula is un- approachable on account of the dense pack ice of the Weddell Sea. The greater part of the east coast of the Palmer Peninsula, except for stretches at the northeast and south ends, are rimmed by shelf ice. The islands and mainland in this coastal sector are for the most part quite mountainous, particu- larly along the northwest and west coasts of the peninsula, and on the South Orkney and South Shetland Islands, where rocky promontories, nuna- taks, and mountain peaks protrude through a mantle of snow and ice. During the summer months the enveloping ice melts back along portions of these coasts, exposing rocky cliffs and in some places stretches of pebble beach. The Palmer Peninsula is one of the most readily accessible parts of the Antarctic mainland. The peninsula and the off-lying islands, particularly the South Shetland and South Orkney Islands, were the sites of some of the earliest landings. Bays within the coastal sector have been used as layover stations by whalers and sealers for many years, and several of the bays have been the sites of regularly maintained supply caches. Numerous landings have been made within this coastal sector and several permanent and semi- permanent camps for exploratory and scientific purposes have been maintained here in recent years. 2. Coast and landing places From Cape Adams to Cape Knowles the coast trends approximately 400 miles northward. Heavy pack, broken by a few open water leads, fronts this mountain-dominated stretch of coast. Scat- tered peaks behind the southern portion of the coast around the Nantucket Inlet reach maximum elevations of about 7,000 feet. Th entrance to the inlet is more or less ice free, whereas the bay itself is choked with ice. PAGE 22650X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 Wright Inlet, which extends into the piedmont about 30 miles north of Nantucket Inlet, contains numerous patches of open water.. At the head of this bay a 5,000-foot-high rock mass, Mount Tricorn, rises above the surrounding terrain and presents a distinctive appearance with its snow- free, nearly vertical rock faces. Between Wright Inlet and New Bedford Inlet, a distance of about 30 miles, the piedmont gradually rises to the in- terior mountains. New Bedford Inlet, which is about 10 n. miles wide at its entrance, is filled with crevassed ice and fringed with cuffed shores that are formed by the vertical, ice-free faces of the piedmont. These cliffs are broken only by a series of glaciers descending steeply from the high, rugged, interior mountains. The head of the inlet is marked by a snow-covered mountain that is rocky on its eastern or bay side. Between New Bedford Inlet and Violante Inlet, the next indentation to the north, mountain masses are isolated and scattered. Several glaciers descend from the high interior. Inside the mouth of Violante Inlet is the small, snow-covered Pullen Island, which is cliffy along its northern coast and gently sloping along its southern coast. A very steep glacier marks the head of the large bay, and the walls of the bay rise to low, ice-cov- ered peaks. The embayed, cape-studded coast continues northward to Hilton Inlet, of which Cape Knowles is the northern entrance point. Low, snow-cov- ered Cape Darlington forms the southern entrance point. The bay is headed by the wide Gruening Glacier, which descends between steep, often bare, rock walls. From Cape Knowles to Cape Agassiz the coast trends north-northwestward for about 350 miles. The irregularly indented, 180-mile-long stretch of coastline between Cape Knowles and the southern tip of Hearst Island is accessible through several leads in the sea ice, but from Hearst Island to Cape Agassiz the coast is fronted by the Larsen Ice Shelf. The coast between Cape Knowles and Cape Boggs is indented by a succession of inlets and, in general, consists of cliffed headlands and vertical, often snow-free, rock walls. Coastal islands in this area are described as "high, snow-covered mounds." The Cape Knowles ? Cape Boggs por- tion of coast is dominated by Mount Andrew Jackson, which attains a height of 13,750 feet and towers above the high interior plateau. ?A coastal range of lesser elevations lies between Mount Andrew Jackson and the coastline. Lehrke Inlet, the northern entrance point of which is Cape Boggs, appears to be the only one of the Richard Black Coast bays bordered by any appreciable coastal lowland areas, and here the PAGE 22-68 NAVY - JANUARY 1956 lowlands are enclosed by steep icefalls along the edges of the massive coastal ridges. Cape Boggs, a precipitous headland, marks the seaward edge of the high, rugged Eternity Moun- tains, which are reported to rise about 6,000 feet above a 6,500-foot-high plateau farther inland. The northern side of the peninsula ending in Cape Boggs forms the southern shore of Smith Inlet, a large bay at the head of which is a steep glacier. High coastal cliffs extend around the bay to Cape Collier, the northern entrance point of Smith Inlet. The mainland north of Cape Collier is terraced but presents a fairly even skyline. Along this portion of coast there are not as many rock out- crops as elsewhere on the Cape Knowles ? Cape Agassiz stretch of coast. Hearst Island, which lies within the southern limits of the Larsen Ice Shelf, is approximately 42 miles long from north to south. The eastern coast of the island is fronted by heavy sea ice with pressure ridges and several icebergs, and the western or landward coast is bounded by the ice shelf. Hearst Island is snow-covered and crevassed; no bare rock is visible. Behind the ice shelf the mainland coast west of Hearst Island and northward to Cape Agassiz is rugged, with cuffed headlands separat- ing broad, steep glaciers. Bare rock is visible on many of the vertical fault walls and cliff faces. From Cape Agassiz to Cape Longing the coast is approximately 350 miles long along the seaward edge of the Larsen Ice Shelf. Except for the southern shore of the peninsula ending in Cape Longing, the mainland coast is completely fronted by this massive ice shelf, which extends seaward for 10 to 100 n. miles. The Weddell Sea, which fronts the ice shelf, is beset almost constantly by heavy pack ice that constitutes an extreme navi- gational hazard and makes approach to the edge of the shelf very difficult. The absence of sound- ings in this portion of the Weddell Sea evidences the inability of vessels to thus far penetrate these icefilled waters. The edge of the ice shelf itself presents another problem. Changing from year to year in location, height, and configuration and even showing a con- siderable variation from season to season, its loca- tion and description is at best an approximation. The face of the shelf along the southern and cen- tral_ portions of the coast is considerably higher than it is along the northern portion. The central part of the Larsen Ice Shelf is heavily crevassed, and along its seaward edge, which sometimes reaches heights of 100 to 200 feet, it is marked by overhanging cliffs and deep indentations. The shelf increases perceptibly in elevation shoreward. The northern part of the Larsen Ice Shelf slopes downward toward its northern end. CONFIDENTIAL 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY-JANUARY 1956 MILITARY GEOGRAPHY CONFIDENTIAL All of the islands between Cape Agassiz and Cape Longing lie inside the edge of the ice shelf, thus promoting considerable disagreement as to their extent and even to their existence. Several small nunataks are reported, particularly near the mainland coast'. Jason Island, which lies off the center of the Cape Agassiz - Cape Longing stretch of coast, is reportedly snow free in its lower parts. The island's eastern extremity, Cape Framnes, is a bold, conspicuous promontory that extends beyond the edge of the shelf at times. Robertson Island, a dome-shaped, snow-covered island about 35 n. miles south-southwest of Cape Longing, has an extinct volcano at its northern end. Lindenberg Island, a high, dark, and much smaller, island about 8 n. miles northward, is re- ported to be an extinct volcano. The Seal Nuna- taks, a chain of about 11 snow-free islets of vol- canic origin, extend west-northwestward from Robertson Island. Between Cape Agassiz and Cape Northrop, about 80 miles northwestward, the mainland coast is indented by Mobiloil Inlet and a number of smaller inlets. Mobiloil Inlet, located well within the Lar- sen Ise Shelf, is dominated by a myriad of glaciers converging at the head of the inlet at Hub Nuna- tak, and the complex is known as The Traffic Circle. Between Cape Northrop and Mill Inlet, about 35 coastline miles to the northeast, the coast is dominated by a series of steeply sloping, snow- capped peaks and ridges. The glacier in Mill Inlet is about 8 miles wide at its mouth and extends inland a considerable distance between the rock walls of a valley. From Mill Inlet northeastward the coast is bor- dered by a series of peaks and ridges with almost perpendicular cliffs. The northern and eastern slopes are snow free while the separating valleys are filled with ice. The Richthofen Valley, about 80 miles north- east of Mill Inlet, is a glacier-filled depression that is about 7 miles wide at its mouth and extends inland some 15 miles between steep rock walls. The southern portion of the 75-mile-long Oscar II Coast, extending northeastward from the valley, is indented by several inlets separated by rugged promontories. Behind this stretch of coast the steepgedges of the interior plateau are broken in places by steep glaciers. North of the glaciers the coastline is indented by a series of long, deep em- bayments bordered by steep rock peninsulas. The Nordenskjold Coast, which constitutes the northern part of the coast between Cape Agassiz and Cape Longing, is a high, ice-covered plateau with a steeply sloping seaward fringe. A number of glaciers descend onto the ice shelf that fronts CONFIDENTIAL the southwestern part of this coast. Deep fiords extend several miles inland along the rest of the coast, which is dominated by Cape Sobral, a partly snow-free promontory that appears to be an island from the air, and by Cape Longing, 12 miles away across Larsen Inlet. From Cape Longing to Cape Dubouzet the coast trends northeastward for 150 miles. Several large islands front most of the mainland coast, which is covered by an almost continuous ice sheet and fronted by ice cliffs and nearly always frozen coastal channels. Approaches are blocked by the icepack throughout most of the year. From No- vember through February the icepack is broken, but the approaches are imperilled by heavy float- ing ice. Anchorage is reported available in 6 fathoms over good holding ground about 100 yards off the north- west coast of Snow Hill Island, which lies east of Cape Longing. Anchorage is also reported off the southeast coast of the same island about 1 n. mile offshore in 16 fathoms over good holding ground. A third anchorage is reported in a bay off the northwest coast of Joinville Island, the largest island off the tip of the Palmer Peninsula. The James Ross Island group is separated from the mainland by the Prince Gustav Channel, which has never been observed to be ?ice free. James Ross Island, the largest of the group, is essentially an ice-covered, table-topped island dom- inated by the large, conical Mount Haddington (6,561 feet) . The coast of the island is indented by bights and is fronted by vertical cliffs and ice- falls interrupted by glaciers that are 1 to 2 mires in width and terminate in ice cliffs. The Naze, a low sandy cape, marks the northeast tip of the island and extends to within 3 n. miles of the rocky, precipitous Vega Island. Vega Island reaches a maximum height of 2,180 feet. Sidney Herbert Sound, which separates James Ross Island from Vega Island, has never been navigated be- cause of the ice conditions and the numerous rocks and islets. Snow Hill Island is separated from James Ross Island to the northwest by Admiralty Sound, a deep but almost always ice-blocked channel. On the northwest coast of the northeastern projec- tion of Snow Hill Island there is a low shore on which landings have been made (landing place (1) ) . The Swedes under Nordenskjold landed in 1901 and were rescued in 1903 by the Argentinians. An American expedition under Ellsworth also made a landing here during 1934-1935. The southeast coast of the projection consists of an ice cliff 4 to 20 feet high. The island's interior icecap rises to a huge level plain which has been utilized as an aircraft landing area. PAGE 22-650X1 L._ Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 Seymour Island, about 1 n. mile northeast of Snow Hill Island, is reported to be entirely snow free. The island is, in general, fringed by low per- pendicular cliffs, but many slopes are gradual enough to provide landing places, particularly on the southeast coast. A small island about 3 n. miles to the north has a beach along its north coast. Andersson Island and Jonassen Island, about 20 n. miles northeast of Vega Island, are separated from the James Ross Island group by Erebus and Terror Gulf. This gulf, noted for variable cur- rents and heavy ice conditions, contains depths of 100 to 200 fathoms. Andersson Island and Jonassen Island are flat topped, and the icecaps of the islands fall in gentle slopes to ice cliffs at the sea. The eastern extremity of Andersson Island.evidences volcanic origin in a lofty precipice composed of an irregular mass of volcanic tuff rising perpendicularly from the sea. A narrow channel, Fridtjof Sound, separates these islands from the mainland and has been safely navigated even when Antarctic' Sound, the -channel farther north between the mainland and the Joinville Island group, was observed to be blocked by heavy pack ice. Paulet Island, the southernmost and smallest of the Joinville Island group, is located about 16 n. miles due east of Andersson Island and is practically snow free. It is apparently volcanic in origin, has terraced slopes, and rises to a cone- shaped summit reaching an elevation of 1,263 feet. The steep slopes of the island are the site of a large- penguin rookery. A low gravel beach bounded by cliffs lies in a deep bight on the east- ern side of the island. Along the northwest coast is a campsite where provisions were left in 1903 by the shipwrecked crew of the Norwegian ship Antarctic. Other islands of the Joinville Island group in- clude Joinville Island, D'Urville Island, Dundee Island, and a number of smaller islands and islets, most of which are connected by sea ice. The group is separated from the tip of the Palmer Peninsula by Antarctic Sound, which is usually blocked by ice. On Joinville Island, the largest of the islands, a mountain reaches an elevation of 3,700 feet. The rest of the group is covered by a low, smooth icecap, bare rock appearing only where surfaces are perpendicular. At the northwestern end of Dundee Island there is a rocky beach (landing place (2) ) backed by a 40-foot-high ice face. Ells- worth landed here during his 1935-36 expedition. Aircraft have landed on the snow plain in the northern portion of the island. - The coastal peaks that emerge from the ice sheet on the mainland between Cape Longing and Cape Dubouzet are the fringes of the interior PAGE 22-70 NAVY-JANUARY 1956 frozen tableland. This inland plateau is high, marked by elevations of 2,000 to 3,000 feet. A peak on Cape Longing is reported to reach an elevation of 5,500 feet, and a large glacier breaks the ice cliffs just north of the cape. The mainland coast trends northeastward from Cape Longing along Prince Gustav Channel to Duse Bay, some 7 n. miles wide and 31/2 n. miles deep. This stretch of the mainland is marked by jutting headlands and ice-filled inlets. The eastern shore of Duse Bay is formed by Tambarin Peninsula, which extends southeastward from the tip of the Palmer Peninsula. The northeast face of the Palmer Peninsula is indented by Hope Bay, which is 13/4 n. miles wide and about 2'/2 n. miles long. A British stone hut and meteorological sta- tion have been located within the bay in Hut Cove since 1946. Landings have been effected inside the cove (landing place (5) ) and southwest of the western entrance point. The ice cliff be- tween Hope Bay and Cape Dubouzet is the sea- ward edge of a vast glacier. The South Orkney Islands, some 345 n. miles northeast of the tip of the Palmer Peninsula and lying between latitudes 60?S. and 61?S., consist Of two barren, mountainous islands and a number of smaller islands and islets. The main islands, Coronation and Laurie Islands, have a combined coastline length of only about 100 miles. Ap- proaches to the group are hazardous because the islands are inadequately charted, are covered usu- ally by fog, and are fronted by icebergs, rocks, and shoal areas. Tide rips which may be caused by sunken rocks are common, and the combina- tion of floating ice and currents makes naviga- tion close off the coasts and between i the islands extremely dangerous. Coronation Island, the largest of the South Ork- ney Islands, is about 30 miles long and 3 to 8 miles wide. It is dominated by a mountain ridge that extends the length of the island and reaches its greatest height in the eastern part where it ascends to 3,000 feet. Completely glaciated, the terrain of the island descends steeply to the sea in rugged cliffs except along the northern and northwestern coasts where the icecap descends to the water's edge in gentle slopes. All coasts are indented, but the anchorages in the indentations are for the most part temporary at best. Only Sandefjord Bay on the west coast has desirable conditions for anchoring. Here the holding ground is good in 5 to 18 fathoms and shelter from the weather is provided by headlands and nearby islands. In the bay and throughout the surround- ing waters, great care must be taken to avoid the numerous rocks and bergs, both grounded and afloat. Landings have been made on the western part of Coronation Island (landing place (4) ). CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY-JANUARY 1956 MILITARY GEOGRAPHY Laurie Island, the other major island of the group, is considerably smaller, being only about 12 1/2 miles long and in places less than 1 mile wide. The island is essentially a complex of ice- covered peninsulas separating several embayments. Scotia Bay, an embayment at the western end of the south coast, has been the site of an Argen- tine meteorological station since 1904. Anchorage may be taken in 8 to 10 fathoms in the entrance of a cove at the north end of the bay; however, anchorage is not recommended in the bay because the holding ground is poor, the bay is exposed, and the cove is small. In this cove, which is the location of the Argentine station, landings have been effected (landing place (3) ) . The bay en- trance is flanked by some of the numerous rocks and islets that encircle the island. Scotia Bay is ice locked during the winter, as is the entire island group, and is clear of ice for only a short time during the summer. South of Coronation Island are several islands, islets, and rocks. Several good anchorages are available in this area, which has long served as a station for whalers. Borge Bay, located off the east coast of Signy Island, is one of the more frequented anchorages. On the west shore of the bay there is a good beach where fresh water is available. Powell Island,- east of Coronation Island, and two smaller islands form Ellefsen Harbor, a small but well-sheltered anchorage with depths of 8 to 13 fathoms over good holding ground. The South Shetland Islands are separated from the northwest coast of the Palmer Peninsula by Bransfield Strait, which is 60 to 70 n. miles wide. The islands are arranged in a chain that extends in an east-northeast - west-southwest direction for a distance of approximately 280 n. miles. The island chain is divided into two groups by a broad strait that is about 65 n. miles wide and contains a few relatively small islands. The most important islands in the northeastern group are Clarence Island and Elephant Island, and in the southwest- ern? group are King George Island, Livingston Island, and Deception Island. The islands are of volcanic origin, mostly mountainous, and range in size from tiny islets to King George Island, which is 48 miles long and 18 miles wide. Approaches from the north to most of the South Shetland Islands are restricted by a gently sloping insular shelf; by numerous islets, rocks, and sub- merged obstacles extending far offshore; and by strong currents. Strong currents also flow through the narrows between the islands. Navigable chan- nels allow passage between most of the islands, and approaches to the group from the south are clear except for scattered islets, rocks, and reefs, most of which are found close offshore. CONFIDENTIAL CONFIDENTIAL The larger islands of the South Shetland Islands are indented by many large bays providing ade- quate shelter for anchorage. Many of these bays have been used or visited by whaling and sealing vessels. A British meteorological station and an Argentine meteorological station are located on the shores of the bay that is enclosed by the horseshoe- shaped Deception Island (FIGURE 22-49A) . In ad- dition to the larger embayments, numerous pro- tected coves indent the coasts of almost all of the larger islands. The coasts of the South Shetland Islands are steep, consisting of ice cliffs and barren rocky bluffs. Many of the smaller islands are little more than bare, steep-sided conical rocks jutting up from the water. A few islands have low, almost flat profiles, but most of the islands have rugged, mountainous interiors. All but the aforemen- tioned steep-sided, conical islets are capped with snow and ice. Sheltered sand and gravel beaches suitable for landings are available on Clarence Island, King George Island, and Deception Island (landing places (6), (8), and (10)). From Cape Dubouzet to Cape Kater the coast of the Palmer Peninsula trends southwestward for about 100 miles and is indented by a few partly sheltered bays and several minor indentations. The coast is covered by ice through which only a few pinnacles project. Bransfleld Strait, which separates the Palmer Peninsula from the South Shetland Islands is, in general, clear. The strait is approximately 38 to 64 n. miles wide. Ap- proaches from the strait to the coast are partly obstructed by two small islands, each about 21/2 miles in diameter. One of the islands lies 'about 10 n. miles off Cape Kater and the other lies' about 11 n. miles off the center ,of the coast bkween Cape Dubouzet and Cape Kater. In addition, num- erous islets, rocks, and reefs are found in the vicinity of each island and as far as 12 n. miles off portions of the mainland coast. The shores of the mainland are mostly fronted by ice cliffs. However, a few bare rock and pebble beaches are found at the tips of promontories and at the foot of ice cliffs. Two of the promontories were used as landing places (landing places (7) and (9) ) . The entire coast is backed by an almost featureless plateau that is about 2,000 feet high behind the northeast end and 6,000 feet high behind the southwest end of the coast. Numerous glaciers flowing northward off this plateau join to form an almost level ice platform that extends to the sea. The Palmer Archipelago, which consists of Trin- ity Island, Brabant Island, Anvers Island, and smaller associated islands, extends northeast - southwest for 135 n. miles off the northwest coast of the Palmer Peninsula between _Cape Kater and Cape Renard. Approaches to the islands of this Declassified in Part - Sanitized Copy Approved for Release PAGE 22-7150X1 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 group are clear from the open sea to the north and northwest and through Bransfield Strait to the northeast. Passage between the group and Palmer Peninsula, however, is restricted to a con- tinuous channel that is composed of several straits and has a minimum width of 3 n. miles between Trinity Island and the mainland. The channel is encumbered by islets and rocks, the greatest con- centration of which are found at the southwest en- trance of the channel off the south coast of Anvers Island. Approaches to the east coast of Anvers Island and the west coast of Brabant Island are through a broad bay that is partly obstructed by a group of islands. This bay narrows to the south to a channel 11/2 n. miles wide. Approaches to por- tions of the northeast coast of Brabant Island and the south coast of Anvers Island are restricted to narrow channels by close-lying islands. The chan- nel off the northeast coast of Brabant Island is short, encumbered by several small islands, and about 2 n. miles wide. The channel along the south coast of Anvers Island is approximately 19 n. miles long, 1 to 3 n. miles wide, and channelized at either end by smaller islands. The remaining islands of the archipelago are small and are lo- cated far enough apart from one another and the mainland to have relatively clear approaches. In places, however, the approaches to the islands are encumbered by groups of islets and rocks extend- ing a maximum of 5 n. miles offshore. A good anchorage reportedly used by whaling vessels is available off the west coast of Wiencke Island, which is located off the south coast of Anvers Island. The harbor is sheltered from wind, swell, and drift ice by a smaller island and several rocks. Trinity Island, which is approximately 15 miles long and 13 miles wide, lies 3 to 17 n. miles off the Palmer Peninsula coast and is located about 18 n. miles west of Cape Kater. Approaches to large portions of the coast of this island are fouled by rocks and reefs for a distance of 5 n. miles offshore. The southwest portion of the island consists of an -ice-covered tableland that merges with the high, partly exposed rock characteristic of most of the island. The summit, 3,670 feet high, is located ap- proximately at the center of the island. Brabant Island, which is 33 miles long and 20 miles wide, lies 4 to 28 n. miles off the mainland and about 64 n. miles west-southwest of Cape Kater. The island is predominantly mountainous with bare rock showing only on the peaks and steeper slopes. A landing was made on the northern portion of the island (landing place (11) ) . Several small islands and numerous islets and rocks encumber the ap- proaches to parts of the coast of the island, and foul ground extends as far as 5 n. miles off the west coast of the northern extremity of the island. PAGE 22-72 NAVY - JANUARY 1956 Several of the bays indenting the coast of the island offer possible shelter, but most of the bays contain encumbrances. The east coast of Brabant Island is backed mostly by the ice cliffs of glaciers rising to the snow-covered foothills and peaks of a mountain range that parallels most of the coast. The northern extremity of the island is a high rocky peninsula, much of which is fronted by high rocky cliffs. The west coast is intersected by moun- tain ridges ending in rocky promontories, between which are cliff-faced glaciers descending through valleys. Of the several mountain peaks that closely back the west coast of the island, the highest reaches an elevation of 8,054 feet. Anvers Island, which is 43 miles long and 28 miles wide, lies about 8 to 40 n. miles off the mainland and is separated from Brabant Island by a bay, 4 to 18 n. miles wide. Islets, rocks, and shoals ex- tending as far as 6 n. miles offshore are found in great numbers off the north, west, and southwest coasts. Only scattered encumbrances lie off the other coasts of the island. The southeast coast of the island is fronted by steep rocky cliffs from which icefalls and hanging glaciers descend to the shore. The glaciers originate in the valleys of a mountain range. The peaks of the range attain the highest elevations found on the island, almost 10,000 feet. The remaining highly indented coasts of the island are bordered by a belt of piedmont ice that is backed by glaciers descending from the rugged mountainous interior. Landings were made on the southwest part of Anvers Island (land- ing place (17) ) , but elsewhere the shores of the island afford only a few possible landing sites. The remaining islands of the Palmer Archipelago are considerably smaller than Brabant Island and Anvers Island, and most of them are found in the body of water between Brabant Island and Trinity Island. The small islands are predominantly mountainous with coasts backed by rock cliffs, cliff-faced glaciers, and gentle, snow-covered slopes. Landings were made on three of these small islands close off Anvers Island (landing places (13) , (14), and (16)). From Cape Kater to Cape Renard the mainland coast trends southwestward for about 200 miles. This irregular stretch of coast has many embay- ments and is sheltered by the Palmer Archipelago. Approaches to the coast are restricted to numerous straits and passages by the islands of the Palmer Archipelago, which extend as far as 40 n. miles off- shore. Passage between the mainland coast and the islands is through a strait that is 3 to 11 n. miles wide but is encumbered by islets, rocks, and reefs. The approaches from the strait to the mainland coast are encumbered by many islets and rocks that are,found off most of the promontories and at the heads of several of the bays. Sheltered an- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY-JANUARY 1956 MILITARY GEOGRAPHY chorages are available in many of the bays, though the usefullness of these Anchorages is severely limited by the danger of the calving of encircling ice cliffs. Most of the coast between Cape Kater and Cape Renard is fronted by the rice cliffs of glaciers. How- ever, bare rock is found on many of the promon- tories and on the sides of the numerous narrow glacial fiords indenting the coast. A few land- ings were made on the southwest half of the coast (landing places (12) and (15) ) . The coast is characterized by numerous rocky promontories ex- tending inland as ridges to a high interior plateau that has an approximate elevation of 6,000 feet. Many glaciers descend from the plateau between the ridges. From Cape Renard to Cape Rey (66?44'S., 66?30'W.) the mainland coastline trends southwest- ward for about 240 miles and is extremely irregular. Approaches to the northeast part of the coast are restricted by a concentration of small islands, islets, and rocks lying from a few hundred yards to 32 n. miles offshore. Approaches to the southwest part of the coast are channelized by the Biscoe Islands, 16 to about 50 n. miles offshore, and by numerous smaller islands, islets, and rocks in the strait between the Biscoe Islands and the mainland. The Biscoe Islands lie in a northeast - southwest line that roughly parallels the mainland coast for a distance of approximately 85 n. miles. The islands vary in length from 2 to 25 miles and all are relatively low (maximum elevation 600 feet) , featureless, and covered by ice. Rock is exposed only at the bases of some of the ice cliffs that rim most of the islands. The islands are all oriented with their lengths parallel with the axis of the island chain. On some of the islands the icecap summit is located closer to the southwestern end of the island. Three small islands lying 1 to 4 n. miles off the portion of the mainland coast just southwest of Cape Renard restrict approach to that part of the coast to a narrow channel. The small islands are snow- and ice-covered rock masses, with an eleva- tion of 2,100 feet recorded on the largest island. Fiords indenting two of the islands have been used as anchorages. The mainland coast for about 100 miles south- west of Cape Renard is indented by several bays 8 to 14 n. miles long. The bays are separated by narrow strips of land, many of which terminate in high, cliff-faced promontories. A few small islands, 1 to 3 miles in diameter, lie close off some of the promontories and restrict entrance into several of the bays. Although most of these islands have bold profiles and reach elevations up to 2,500 feet, land- ings have been made on two of them (landing places (18) and (19)). Near the southwest end, CONFIDENTIAL CONFIDENTIAL the mainland coast is indented by Marin Darbel Bay, a broad embayment situated between Cape Bellue and Cape Rey. Most of the coast is rimmed by ice that joins with the calving ice cliffs of the valley glaciers at the bayheads; however, a landing was made at one point (landing place (20)). A particularly broad glacial sheet formed by several valley glaciers lines the shores of Marin Darbel Bay. Valley glaciers dissect the high plateau (elevation 6,000 feet) closely backing the entire coast. Nu- merous ridges extend seaward from the plateau and end in rocky promontories. J, From Cape Rey to Camp Point (67?58'S., 67?19'E.) the coast is about 220 miles long. The greater part of the coast is shielded by Adelaide Island, which lies close off a broad, mountainous cape that dominates the mainland coast. Ap- proaches are through Matha Strait and Marguerite Bay, located to the north and south respectively of Adelaide Island, and through a strait 50 n. miles long and 3/4 to 19 n. miles wide that separates Adelaide Island from the mainland. Passage through Matha Strait is, in general, clear through a broad strait separating the Biscoe Islands from Adelaide Island. The strait is encumbered only by a few scattered groups of islets. Approach to the mainland from the south through Marguerite Bay is restricted by a chain of islets, rocks, and reefs that extends more than 20 n. miles south of Ade- laide Island. An island approximately 5 miles in diameter and several smaller islands divide the northern part of the strait between Adelaide Island and the mainland into two channels. Four elon- gated islands, 3 to 7 miles long, channelize passage through the narrower part of the strait to the south. Farther south, Pourquoi Pas Island and several smaller islands channelize approaches to the ex- tremely irregular southern part of the mainland coast. The channels are mostly clear, as much as 25 n. miles long, and 1/2 to 7 n. miles wide; how- ever, they are difficult to navigate because of the strong currents that flow through the narrows and the strong local offshore winds. Adelaide Island is approximately 78 miles long and 35 miles wide. Approaches to portions of the north, south, and east coasts of the island are en- cumbered by groups of islets, rocks, and shoals. A range of mountains separated into five distinct masses trends the length of the island. The steep, snow-covered mountain slopes drop off sharply to the irregular east coast of the island, while the west coast of the island is backed by a broad snow- and ice-covered terrace that spreads seaward from the base of the mountains. The shores of the west coast consist of calving ice cliffs, 100 to 140 feet high, that are notched by numerous minor in- dentations. PAGE 222,50X1 6. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 Pourquoi Pas Island, which is 17 miles long and 15 miles wide, and the other smaller islands restrict- ing approaches to the southern part of the Cape Rey - Camp Point stretch of coast are distinguished by the predominance of steep, bare cliffs lining their shores. Snow- and ice-capped mountains reach maximum elevations of 5,400 feet on Pourquoi Pas Island and more than 3,000 feet on the smaller islands. A comparatively regular stretch of mainland coast about 45 miles long fronts the broad cape of land that is closely bordered by Adelaide Island. A mountain chain with a maximum elevation of over 5,500 feet extends north-south parallel' to the coastline of the cape. From the mountain chain steep, snow-covered slopes and valley glaciers descend to the strait. The north coast of the cape is indented by a large fiord 22 n. miles long and 10 to 12 n. miles wide, the head of which is rimmed by several valley glaciers. The fiord is bounded on the east by steep rock cliffs and on the west by the ice cliffs of a glacial mass that descends from the mountainous interior of the cape. The south coast of the cape is backed by steep rocky slopes that flank the ice cliffs of a valley glacier extending northward across the neck of the cape to the fiord. The remainder of the mainland coast south of the cape to Camp Point is unusually free of ice and is indented by a bay and several fiords. Valley glaciers descend from the high interior plateau and fill the heads of the fiords. The walls of the fiords consist of bare rock. Landing places might be found on the raised beaches and glacial moraines at the foot of the cliffs along portions of this part of the mainland coast. Between Camp Point and Cape Jeremy (69?24'S., 68?51'W.) , a distance of about 170 miles, the coast is almost entirely bordered by ice cliffs. The domi- nant terrain feature, a continuation of the high Interior plateau, decreases in altitude to the south and gives way to a rift valley behind the south- ern part of the coast. This rift provides an over- land link between the east and west coasts of the Palmer Peninsula. Approaches to this stretch of coast are through Marguerite Bay, a large body of water 130 n. miles long and 60 n. miles wide (FIGURE 22-49B). The entrance to the bay is quite broad, extending more than 60 n. miles between Adelaide Island to the north and Alexander Island to the south. The northern part of the entrance is fouled by a chain of islets, rocks, and reefs that extend more than 20 n. miles south of Adelaide Island. Navigation within the bay is restricted by scattered groups of ice-covered islets and numerous uncharted, sub- merged pinnacles. Marguerite Bay is generally filled with ice, even throughout most of the sum- PAGE 22-74 NAVY 7 JANUARY 1956 mer months. When most of the bay is relatively clear, navigation is still hazardous in the south- ern part of the bay because of the large quantity of sea ice and bergs carried there by prevailing northerly winds. Several ice-covered islands ranging in size from tiny islets to islands 4 miles in diameter restrict approaches to the northern portion of the main- land coast. These islands lie 6 to 17 n. miles south of Camp Point and extend as far as 5 n. miles directly offshore. One of the islands, Stonington Island, has-been used as a base camp for several expeditions (landing place (22) ). Groups of islets, rocks, and reefs front a promontory located 20 n. miles south of Camp Point, lie as far as 8 n. miles off a cape located 48 n. miles south of Camp Point, and extend a few hundred yards to 24 n. miles northwest of Cape Jeremy. The Camp Point - Cape Jeremy stretch of coast is indented by a fiord and several bays, the largest of which fronts most of the southern part of the coast. A landing was made on the northern part of the coast by the British expedition of 1934-1937 (landing place (21) ). Most of the shore is imthe- diately backed by the ice cliffs of piedmont glaciers. The glaciers are relatively narrow along the north- ern part of the coast, but widen southward to a width of 18 n. miles and fill most of the large bay that indents the southern part of the coast. Back- ing the coastal ice are the steep slopes of mountain peaks, ridges, bluffs, and blunt promontories be- tween which numerous glaciers descend seaward from the high interior plateau. A fiord 7 n. miles long and 31/2 n. miles wide lies 18 n. miles south of Camp Point. The fiord is flanked by the steep cliffs of the plateau to the north and a promontory to the south. At the head of the fiord is a large glacier which flows northwest from a vast interior basin. The glacier also flows southeast from the basin to the Bowman Coast on the east coast of the Palmer Peninsula. Several other glacial val- leys merge in this basin and offer sledge routes between the east and west coast's of the peninsula. Between Cape Jeremy and the western entrance of Carroll Inlet the coast is about 500 miles long and is sheltered by Alexander I Island, a large crescent-shaped land mass approximately 260 miles long and 170 miles wide. This island is separated from the mainland by a rift known as George VI Sound, which is almost entirely filled with shelf ice that renders the sound virtually impenetrable by vessels. Approaches to most of the south and east coasts of Alexander I Island and to the bordering main- land coast are obstructed by shelf ice that is edged by ice cliffs and has an extremely irregular sur- face composed of pressure ridges, hummocks, rifts, and depressions. However, the northeastern part CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50 ? ? NAVY - JANUARY 1956 MILITARY -Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 of George VI Sound for 25 to 35 n. miles south of Cape Jeremy and the southwestern part of the sound through Ronne Entrance are relatively free of ice. Approach to the mainland south of Ronne Entrance is restricted by several islands ranging in size from less than a mile in diameter to more than 70 miles in length. Passages that separate these islands from each other and froin the main- land are almost entirely filled with extensions of the shelf ice of the sound. Approach to the west coast of Alexander I Island is encumbered by Char- cot Island, which is approximately 55 miles in diameter. Passage by vessel between Charcot Island and Alexander I Island is blocked by shelf ice that almost completely fills the intervening Wilkins Strait. Groups of islets restrict approaches to the north end of Alexander I Island, and nu- merous rocks, reefs, and other obstacles, most of which are uncharted, make approaches hazardous to much of the remainder of the island. Most of the mainland coast, the coast of Alex- ander I Island, and the coasts of the smaller off- lying islands are rimmed by ice cliffs with few possible places for landing; however, a landing was made on the northern coast of Charcot Is- land (landing place (23) ). Broad piedmont gla- ciers broken in places by scattered nunataks back the north and west coasts of Alexander I Island and the mainland coast south of Alexander I Is- land. Rising from the piedmont ice in the north- ern part of Alexander I Island are the steep, barren slopes of several mountain ranges, the peaks of which attain maximum elevations of over 10,000 feet. The mountain slopes lie close behind most of the north half of the east coast of the island. The coasts of the southern part of Alexander I Island and most of the mainland coast are backed by isolated mountains and groups of mountains between which broad glaciers gradually descend from the interior highlands. Charcot Island and the smaller off-lying islands are almost completely capped by snow and ice. A few mountain peaks back the north coast of Charcot Island, and scat- tered terrain features appear through the mantle of snow and ice on the smaller islands. D. Coastal Sector 2: Western entrance of Carroll Inlet to Cape Colbeck, including Peter I Island 730s., 790W.; 770-. b, 158?W. (FIGURE 22-76; USHO Charts 6637 and 6638) 1. General The mainland stretch of coast between Carroll Inlet and Cape Colbeck is approximately 2,200 miles long and fronted by exceedingly heavy pack ice. Aerial survey has revealed little of the coastal configuration because ice covers the coast and CONFIDENTIAL GEOGRAPHY CONFIDENTIAL extends seaward. The only landings effected in Coastal Sector 2 were on Peter I Island, about 240 n. miles north of the eastern part of the coastal sector, and on Edward VII Peninsula, located at the western extremity of the coastal sector. The South Pacific Ocean lies off the entire coast, though the Bellingshausen Sea and Amundsen Sea immediately border the east half of the coastal sector. Areas of open water are reported along-the coast of the central and western portions of the coastal sector; however, passage through the pack has never been achieved. The approach of the one landing effected on the mainland coast of this coastal sector was made through the Ross Sea. Coastal terrain behind the almost continuous ice cliffs is generally described as rugged, consist- ing of numerous coastal ranges and isolated mountain massifs. The Ellsworth Highland of the central and eastern part of the coastal sector lies between the coastal ranges and the interior plateau. Heights in the Ellsworth Highland reach about 12,500 feet. The coastal ranges are, in general, somewhat lower, but two coastal peaks midway along the coastal sector are reported to reach 15,000 feet. 2. Coast and landing places etween Carroll Inlet and Cape Flying Fish the coast is approximately 500 miles long and is bordered by the Bellingshausen Sea. During the summer, pack ice probably extends about 180 n. miles from the coast, but ice conditions are dif- ficult to forecast. It is considered likely that no open water exists along this stretch of the main- land coast during the summer as it does along many other portions of the. coast. Between Carroll Inlet and about 85?W. longi- tude, the coast is called the George Bryan Coast and consists entirely of ice cliffs. Behind this coastal stretch lies the highland belt called the Ellsworth Highland, which extends from the base of the Palmer Peninsula to the interior continental plateau. A mountain range dominated near its northern end by the 12,500-foot Mount Ulmer lies a considerable distance inland in the highland belt. From 88?W. to about 100?50'W. the coast is called the Eights Coast. The coastline at the west- ern end of this stretch of coast is not charted be- cause of the irreconcilability of the sources. Near 97?W. longitude the coast trends northward along the Noville Peninsula, which ends in Cape Palmer. At the base of the peninsula is a 4,000-foot-high mountain and a mountain range about 3,000 feet high extending nprthward to the tip of the pen- insula. The eastern side of the peninsula is in- dented by bays that are probably always filled PAGE 22-750X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 with shelf ice. The two Fletcher Islands lie just off this coast. The Thurston Peninsula, of which Noville Pen- insula is an offshoot, extends northwestward and westward for about 80 miles and terminates in Cape Flying Fish. The only landings in the area have been made on Peter I Island, located about 240 n. miles north of the mainland coast (FIGURE 22-50A). Extend- ing about 14 miles in a north-south direction, the island is covered by snow and ice except where slopes are precipitous. The Norwegians in 1928- 1929, and again in 1947-1948, and an American expedition in 1947-1948 have landed on the island (landing place (24) ). The greatest elevation on Peter I Island is an extinct volcano which reaches a height of about 4,000 feet. The east coast is precipitous while the west coast is lower but contains a high piedmont in its central portion. Both the northern and southern sides of the island have more gradual slopes and terminate in low ice cliffs. The cliffs, which look very much like cliffs of shelf ice, appear to be afloat in some places, but in other places a narrow shelf of bare rock is visible at the water's edge. Twin glaciers cut the northern coast. Anchorage in 21 fathoms over sand and volcanic stones is available in a bay along the island's west- ern coast, but little shelter is afforded from the winds. Between Cape Flying Fish and Cape Dart, ap- proximately 410 n. miles west-southwestward, the coast is about 1,000 coastline miles in length and consists mostly of peninsulas separated by bays. The extent and shape of most of the bays are un- known. When observed from the air (1946-1947) all but one small embayment were almost com- pletely filled with shelf ice. This stretch of coast is bordered by the Amundsen Sea. Because of heavy pack ice in the approaches to this coast, no vessel has thus far been able to reach the continental shores. From the air long stretches of open water have been observed along the shore of the western part of the coast. Several islands lie in the approaches to the main- land; two groups of small islands are located in the southeastern part of Amundsen Sea, and three large islands lie mostly within the edge of the shelf ice in the large bays along the central part of the coast. From Cape Flying Fish to the head of Pine Is- land Bay, located about 180 n. miles to the south, the coastline is highly irregular. Except for one small embayment on the south side of Canisteo Peninsula, which is about 110 n. miles south of Cape Flying Fish, the embayments in this part of the coast were mostly covered by shelf ice during PAGE 22-76 NAVY - JANUARY 1956 1946-47. The coast is backed by mountains about 1,800 to 3,400 feet high. From the head of Pine Island Bay the shore trends westward for about 240 miles to the base of Martin Peninsula. Two bays separated by Bear Island and an ice tongue are features of the coast- line. Bear Island, which is about 52 miles long from north to south and 32 miles wide, is en- veloped on the south and west sides by the shelf ice. Martin Peninsula, about 25 to 33 n. miles west of Bear Island, projects about 90 miles north- ward. This part of the coast is backed by an extensive coastal mountain range about 7,000 feet high. Between the northernmost point of Martin Pen- insula and Cape Dart, about 190 n. miles west- ward, the coast is indented by a large and a small bay separated by a peninsula that is about 75 miles wide along its seaward edge. The large bay as charted is about 55 n. miles wide between Mar- tin Peninsula and the broad peninsula to the west, but other dimensions and the shape of the embayment are unknown. An island about 25 miles long and 11 miles wide lies in the middle of the entrance of the bay. The extent and shape of the smaller bay is unknown though it is charted as being about 28 n. miles wide. The mainland coast from the western entrance point of this bay to Cape Dart is formed by the glaciated slopes of Mount Siple, which rises to about 10,200 feet approximately 10 to 20 miles inland. Elsewhere the terrain behind the Martin Peninsula - Cape Dart stretch of coast is largely unknown, but mountains about 5,000 feet high have been re- ported about 35 miles inland of the eastern part, and an unbroken ice sheet has been reported be- hind the western part. Between Cape Dart and Cape Colbeck the coast trends about 750 miles southwestward and is in- dented by two large bays and three small bays. The large bays are mostly filled by shelf ice, and two of the small bays are almost completely filled by glaciers. The approaches to the mainland coast between Cape Dart and Cape Colbeck are through a wide belt of heavy pack ice. Few ships have penetrated very far into the pack. A vast area of open water was observed in December 1940 to extend from the northern edge of the Getz Ice Shelf, which lies southwest of Cape Dart. Patches of water have been seen in other embayments along this part of the coast, but none of the bays have been found to be ice free. Between Cape Dart and a point about 190 n. miles west-southwestward the coast is indented for about 120 n. miles by a large embayment known as Wrigley Gulf, which is almost completely filled .by the Getz Ice Shelf. The coast of the gulf is CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY?JANUARY 1956 MILITARY GEOGRAPHY composed of steep mountains that are mostly ice covered and separated in places by outlet glaciers from the polar ice sheet. From- the western en- trance point of Wrigley Gulf the coast known as Hobbs Coast trends west-southwestward for about 140 miles to the eastern side of Emory Land Gla- cieF, which is about 25 miles wide. The coast con- tinues west-southwestward for about 90 miles to the northeastern entrance point of Paul Block Bay. This stretch of coast, known as the Ruppert Coast, consists of an ice slope and many snow- covered ridges. Paul Block Bay, which is about 15 n. miles wide, extends eastward into the con- tinent for an unknown distance. The Hobbs Coast is backed by mountains of the Hal Flood range, the 'highest summit of which is about 10,000 feet high. The Ruppert Coast is backed by the north- ern end of the Edsel Ford Ranges, a series of mountain groups about 2,500 to over 4,000 feet high. An island about 35 miles long was re- ported (1940) to lie about 18 n. miles north of the western part of Ruppert Coast, but its existence is doubtful. From the western extremity of Ruppert Coast the coast trends southward for about 100 miles, westward for about 75 miles, and northwestward for about 55 miles, forming the shores of Sulzberger Bay. The bay is about 115 n. miles wide and ex- tends southeastward about 60 n. miles. The east- ern coast of Sulzberger Bay is composed of moun- tains dissected by large glaciers that flow into the bay from the polar ice sheet. The ice sheet reaches the southern coast of the bay through shallow valleys in the form of large glaciers. Rock walls do not clearly mark the borders of the valleys. The western coast of Sulzberger Bay, which is formed by the eastern side of Edward VII Pen- insula, is covered by the ice sheet descending from mountains into the bay as widely crevassed, gla- cier icefalls. Most of Sulzberger Bay is covered by heavy shelf ice which makes the coast inacces- sible to vessels. The largest island in the bay, Guest Island, is about 48 miles long and has a maximum elevation of about 1,200 feet near its eastern end. Except for an 18-mile stretch of coast near the western end, the coast between the southwestern entrance point of Sulzberger Bay and Cape Col- beck, about 65 miles westward, is fronted by heavy shelf ice. The only landing made on the Cape Dart ? Cape Colbeck stretch of mainland coast was effected on the northern side of Edward VII Peninsula by rn- embers of a Japanese expedition in 1912 (land- ing place (25) ). The approach to the coast was made from the west through the Ross Sea. . CONFIDENTIAL CONFIDENTIAL E. Coastal Sector 3: Ross Sea Area, Cape Colbeck to Cape Adare 158?W. to 170?E.; 71?S. to 86?S. (FIGURE 22-76; USHO Chart 6636 and B.A. Chart 3177) 1. General This coastal sector includes the coast of the Ross Sea, an extensive embayment in the South Pacific side of the Antarctic continent about 600 n. miles wide between Cape Colbeck, the northwesternmost point of Edward VII Peninsula and Cape Adare, about 625 n. miles northwestward. Most of the Ross Sea is covered by the Ross Ice Shelf which is about 450 n. miles long north ? south, from the ice cliffs at its seaward edge to the escarpment of the Queen Maud Range, and is about 425 n. miles wide between the western shore of Marie Byrd Land and the easternmost point of Ross Island, the largest island in the western part of the Ross Sea. The approaches to the shores of the Ross Sea and to the face of the Ross Ice Shelf are through a belt of pack ice which varies in nature and position from year to year, in accordance with the weather of the previous season, and which may also vary during any one season. The best approach known thus far is along, or no more than about 4 degrees eastward or westward of, the 180th meridian. Ships have approached the Ross Sea at greater distances from the 180th meridian but more time is required for passage through the pack ice in these waters and the dangers to ships are greater. Southward of the belt, the Ross Sea, except in the northeastern part around Cape Col- beck, has always been free from pack ice during the summer months of the years in which observa- tions have been made. Scott Island lies about 315 n. miles northeast- ward of Cape Adare. A few volcanic islands lie along the western side of the Ross Sea. A few other islands lie in the shelf ice near the east and west sides of the embayment. 2. Coast and landing places The shoreline of the Ross Sea from Cape Col- beck, the eastern entrance point, around the head of the embayment to Cape Adare is' about 1,900 miles, exclusive of indentations. The east- ern shore of the embayment is backed by the ice- covered polar plateau, broken in a few places on Edward VII Peninsula by small peaks of the Rocke- feller Mountains. The other shores are backed mostly by high, glaciated mountain peaks and ridges. Declassified in Part - Sanitized Copy Approved for Release 50X1 PAGE 22-77 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL N S 69 From Cape Colbeck to Ross Island, along the sea- ward edge of Ross Ice Shelf, is about 455 n. miles. The western shore of Edward VII Penin- sula, for about 35 miles between Cape Colbeck and the eastern edge of the Ross Ice Shelf, is an in- accessible ice cliff about 125 to 200 feet high. From this point ice cliffs about 180 feet high form the seaward edge of the Ross Ice Shelf and extend westward to Ross Island with only two known in- dentations. Two other indentations which have previously existed and have been used as landing places or as shelter, no longer exist (1955) . One of the existing indentations, Okuma Bay, about 50 miles south of Cape Colbeck, is about 3 miles wide and indents the shelf ice for about 4 miles near the point where the shelf ice is in contact with the shores of Marie Byrd Land. Al- though a landing was reported to have been made by a Japanese expedition in 1912 (landing place (26) ) , the bay is reported to ordinarily be clear of ice early in the spring, leaving high cliffs which afford no landing places. When observed in Janu- ary 1955, the bay was considered unsuitable for a landing site not only because of the high cliffs but also because of the heavy pressure of the bay ice inside. Vast pressure ridges extend southeast- ward into the shelf ice from the head of Okuma Bay. Kainan Bay, about 50 miles west of Okuma Bay, is about 2/8 miles wide (1955) and recedes about 2 miles into the shelf ice (FIGURES 22-50B through 22-51B). The bay is bounded by the shelf ice which forms cliffs about 35 to 80 feet high around the bay and rises to about 150 feet 2 miles inland. The southern part of the Kainan Bay is bounded by an area of pressure ridges which rise about 15 to 25 feet above the sea. The pressure area extends about 1 to 2 miles hack from the bay with a long prong extending to the southwest and a crescent-shaped arm curving to the east. The pres- sure area has a seaward face of low escarpments about 10 to 30 feet high, behind which a series of isolated knobs and ridges, interspersed with cre- vasses, ,rise above a fairly level snow plain. This plain is depressed about 25 -to 50 feet beloW the general level, of the surrounding shelf ice. A Jap- anese Expedition landed in Kainan Bay in 1912 and the U.S.S. Atka moored to the fast ice, which was about 8 to 10 feet thick, in the bay (landing place (27) ) 21 January 1955. Access to the shelf ice from Kainan Bay was over snow ramps in the southeastern and southwestern corners of the bay in 1955, and also several landings were made on the shelf ice by helicopter from the U.S.S. Atka while the ship was moored to the bay ice. The Bay of Whales area, headquarters site of several Antarctic expeditions, about 32 miles south- Westward of Kainan Bay has been known, in one PAGE 22-78 NAVY-JANUARY 1956 form or another, for more than 100 years (FIGURES 22-52A and 22-52B). Since discovery by James C. Ross in 1842 the width of the entrance to the embayment has varied from about 10 miles to as little as 200 feet (1946-47) and the length, from about 10 to 15 miles. Movement of a considerable amount of ice from the Bay of Whales area has left ice cliffs about 20 to 100 feet high exposed to the open sea and the bay, as it now exists, cannot be used as shelter (1955). The area is formed at the junction of two separate shelf ice systems, the southern shores of which appear to be aground; the ice system which forms the eastern shores moves westward and the system which forms west- ern shores moves northward. Several landings have been made in the Bay. of Whales area, from the sea, and from the air (landing place (28) ). Discovery Inlet, which was a deep inlet in the shelf ice about 75 miles west of the Bay of Whales area, has been destroyed by extensive calving of the Ross Ice Shelf (1955) ; however, the disappear- ance may not be permanent. The U.S.S. Bear of Oakland moored to the ice at the head of the inlet in 1935 (landing place (29) ). The Ross Ice Shelf continues westward (FIGURE 22-53A) to the coast of Victoria Land at McMurdo Sound. Three snow-covered islands are known in the eastern portion of the Ross Ice Shelf. Roosevelt Island, about 103 miles long in a north-south direction, 40 miles wide, and approximately 1,200 feet high, lies in the shelf ice an undetermined distance behind the Bay of Whales area. Another island which lies about 34 miles westward of Roose- velt Island is about 23 miles long, in a general east - west direction, and about 17 miles wide. About 52 miles southeastward of Roosevelt Island lies another snow-covered island which is about 57 miles long, in a northeast - southwest direction, and is about 40 miles wide. This island lies in the entrance to a large ice-filled embayment which ex- tends eastward into the continental plateau. The part of the continental land mass which borders the eastern side of the Ross Ice Shelf, about 500 miles long, has been seen from the air, but very little of it has been explored and it is largely unknown. The shore is entirely covered by the continental ice which appears to move off the continental land mass into the eastern side of the Ross Ice Shelf. That part of the land mass along the southern, southwestern, and western sides of the Ross Ice Shelf and the Ross Sea is much better known, as most of it has been seen from the Ross Sea or from the shelf ice, and some areas have been ex- plored. In general, this part of the shore, where known, is bordered by high mountain ranges which stand up mostly as high rock or ice cliffs, except where broken by a few embayments, or cut down CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18 : CIA-RDP97-00952R000200250001-2 ? NAVY - JANUARY 1956 MILITARY GEOGRAPHY by valley glaciers originating on the seaward side of the structure and by many outlet glaciers from the great ice sheet which covers the vast south polar plateau. The mountains rise to elevations of over 3,000 to about 15,000 feet and stands up in places as much as about 9,000 feet above the ice sheet which covers the polar plateau. Several of the glaciers which flow into the Ross Ice Shelf and into the Ross Sea have been named and described. The southeasternmost is imper- fectly defined on its eastern and northern margins. This glacier, although of comparatively low gradi- ent, appears to bring a large volume of ice from the plateau to the shelf ice. The next four outlet glaciers to the northwest which flow into the south- ern end of the Ross Ice Shelf form a continuous piedmont for about 132 to 138 miles along the shore. The piedmont, deflected northwestward by outflow from the southeasternmost glacier and the ice sheet northward of it, produces extensive folds and other disturbances in the ice sheet be- tween the other glaciers, which may extend some distance into the shelf ice in front of the piedmont. This stretch of the shore consists of outlet glaciers flanked by steep sided remnants of the foothills of the Queen Maud Range, in turn backed by the high tabular mountains of the same range some of which rise to more than 13,000 feet about 15 miles inland. One of the glaciers, the Axel Heiberg Gla- cier, was traversed by Amundsen during the south polar expedition of 1911. For about 155 miles west-northwest to Beard- more Glacier, the shore line is indefinite and in part unknown, but most of it is probably bordered by steep mountains and cliffs. One peak rises to approximately 15,000 feet, about 12 miles inland. From the Beardmore Glacier, the coast trends northwestward for about 190 miles, then north about 160 miles, then turns northeastward for about 115 miles to the edge of the ice shelf at the head of McMurdo Sound, an indentation about 45 n. miles long and 40 n. miles wide between Ross Island and the mainland. Five glaciers are shown on charts of this part of the coast but only two are named and of nine charted inlets which indent the coast, only five are named. Beardmore Glacier, the largest and probably best known has an average width of about 12 miles, is about 100 miles long, and rises from about 200 feet above sea level at the shelf ice surface to more than 7,000 feet where it merges with the plateau ice sheet near the 85th parallel. Mountains over 5,000 to more than 10,000 feet high flank the Beardmore Glacier. On the western side, the rounded peaks of the Queen Alexandra Range are separated by a series of deep valleys cut by glaciers tributary to the Beardmore Glacier. The mountain range bordering the eastern side is CONFIDENTIAL CONFIDENTIAL rugged but not as high and has only two charted tributary glaciers. The largest tributary is on the eastern side of the upper Beardmore Glacier. It is about 15 miles wide and is flanked on the south- ern side by the Dominion? Range which trends southeastwardas a rugged row of peaks over 10,000 feet high. Although the surface of Beardmore Glacier is broken by crevasses and extensive ice- falls, it has been traversed by two exploring parties. The glacier was discovered by Sir Ernest Shackle- ton and traversed by his exploring party in De- cember 1908 in an attempt to reach the south poi, then later, by members of the south polar expedition of Robert F. Scott in 1911. The shelf ice in front of the glacier is corrugated by broad undulations for about 20 miles northward. Koettlitz Glacier lies about 400 n. miles north- northeastward of Beardmore Glacier. This gla- cier is not as well known as Beardmore Glacier but has been traversed twice by exploring parties, the Robert F. Scott Expedition, 1901-1904 and by members of the British Antarctic Expedition, 1910-1913. On the east side of Koettlitz Glacier are two mountains connected by a saddle over 2,000 feet high. The highest and easternmost of the moun- tains, an inactive volcano, is the most conspicuous summit at the head of McMurdo Sound. A long narrow peninsula, about 25 miles long and 5 miles wide, projects southeastward from the slopes of this mountain into the Ross Ice Shelf. Three small islands lie in the ice shelf northward of this peninsula and a number of islets lie farther north in the edge of the shelf ice near the head of Mc- Murdo Sound. The northwest edge of the Koett- litz Glacier flows along the glacierized foothills of a high mountain range which backs the part of the coast from the head of the glacier to the 'lati- tude of the head of McMurdo Sound. Ross Island, bordering the east side of McMurdo Sound, is about 53,miles "long east - west and about 50 miles wide north - south. Four volcanos, one of which is active, dominate the terrain of Ross Island. The highest peak, about 13,350 feet, is the active volcano Mt. Erebus, near the western side, and the lowest is Mt. Bird, about 5,640 feet high, near the northern end of the island. A large geyser about 3 miles south of Mt. Bird was active in 1908. The shores are Mostly steep but are ac- cessible in a few known places. Landings by members of two British expeditions, Carsters E. Borchgrevink in 1900 and Robert F. Scott in 1902, were made near the eastern tip of the island (landing place (30) ). Landings were made and Antarctic expedition headquarters estab- lished at Cape Royd (landing place (33) ) ; Cape Evans (landing place (32) ) (FIGURE 22-53B), about 6 miles south of Cape Royds? and at Hut Point on PAGE 22-79 _ Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 Cape Armitage (landing place (31) ). Many land- ings were made on Cape Armitage while H.M.S. Discovery was frozen in the ice for two winters dur- ing 1902-4. Ernest H. Shackleton established a base on Cape Royds in 1908 and occupied another at Cape Evans in 1914-16 which had been estab- lished by Robert F. Scott in 1911-12. Cape Armit- age has access to the Ross Ice Shelf and hence the mainland, but the mainland is not accessible throughout the year from Cape Royds and Cape Evans because the routes are subject to condition of the bay ice (FIGURE 22-54A). A landing was made on the southwestern side of Beaufort Island, a volcanic island about 1 1/2 miles in diameter ap- proximately 11 n. miles northward of Ross Island. The landing, which was unofficial, was made in 1903 by a sailor from the vessel Morning (landing place (35) ). From McMurdo Sound, the head of navigation along the western coast of the Ross Sea, to Terra Nova Bay the coast trends generally northward for about 180 miles. Part of the western shore of McMurdo Sound, from the shelf ice which forms its head to a point about 30 n. miles north-north- westward, is broken by glaciers, inlets, and high rocky promontories. The rest of the western shore of the sound for about 15 n. miles to the western entrance point is formed by part of an extensive ice piedmont. Several glaciers flow into the western side of McMurdo Sound. A bay immediately west- ward of McMurdo Sound indents the coast for about 6 n. miles. Landings have been made at two places along this part of the coast; on Butter Point (landing place (36) ) near the foot of Ferrar Glacier, and at Cape Bernacchi (landing place (37) ). Ferrar Glacier was first traversed from McMurdo Sound to the polar plateau by Scott's expedition in 1901-04, and members of Shackle- ton's expedition landed on Cape Bernacchi in 1908. This part of the coast has been examined several times by British expeditions based at Ross Island and reconnaissance surveys have been made of most of the area. The shore of McMurdo Sound from near Cape Bernacchi northward for about 15 miles to the western entrance is formed by an ice piedmont which is about 6 to 14 miles wide. The seaward edge of the piedmont is an ice cliff about 5 to 80 feet high. The surface is rough and pitted; near the seaward edge it is furrowed by ravines apparently caused by melt water. The piedmont continues northward from the western entrance of the sound for about 34 miles. From here the coast continues its northward trend about 103 miles to the foot of the Drygalski Ice Tongue, a large ice tongue which projects about 30 n. miles eastward into the Ross Sea immediately south of Terra Nova Bay. Granite Harbor, a large embayment; indents the coast about 28 miles PAGE 22-80 NAVY - JANUARY 1956 north of the western entrance of McMurdo Sound. A small ice tongue projects into the head of this bay. This bay has been visited by ships and a landing was made on the shore near a bluff on the southern side of the bay about 8 miles inside the southern entrance point (landing place (38) ). Most of the shore, from the northern entrance point of this embayment to the foot of the Dry- galski Ice Tongue, rises in cliffs which are heavily glacierized. Several of the glaciers end in long ice tongues extending as much as about 5 miles eastward from this shore into the Ross Sea. This part of coast is backed by mountains from about 3,000 feet to over 8,000 feet high. Franklin Island (FIGURE 22-54B) , about 14 miles long north - south and about 7 miles wide, lies about 60 n. miles southeast of the tip of the Dry- galski Ice Tongue and about 60 n. miles northward of Ross Island. The shores are mostly rock cliffs about 500 feet high except on the western side where ice cliffs about 30 to 100 feet high form the shore. Landings were made on the island in 1841 by Sir James Ross, and in 1900 by Carsters E. Borchgrevink (landing place (34) ). The shores of Terra Nova Bay from the southern entrance point to the head of the bay are formed by ice cliffs, about 50 to 100 feet high, at the seaward edge of the Drygalski Ice Tongue. Except for about 17 miles of low shores near the head of the bay, the remaining shores to the northward are formed by ice cliffs 50 to 150 feet high through which, in places, dark rocks project. A small island, which forms the western side of a cove about 2'/2 miles wide, lies in the ice tongue near the head of Terra Nova Bay. Landings have been made on the northeastern side of the small island (landing place (39) ) and the British Antarctic Expedition of 1910-13 established a food depot near the landing place. Two other small islands lie close offshore about 25 n. miles west-southwest- ward of Cape Washington. Pack ice drifting out of the western side of the Ross Sea is deflected by the ice tongue south of Terra Nova Bay and con- sequently, in most years, during the summer Terra Nova Bay may ordinarily be free of drifting pack ice. This part of the shore is backed by moun- tains about 3,000 to more than 9,000 feet high. From Cape Washington, the northern entrance point of Terra Nova Bay, to Cape Adare the coast trends irregularly northward. Wood Bay indents the coast northward of Terra Nova Bay for about 20 n. miles. The southern shore of the bay is mostly ice cliffs, which are the seaward edge of the ice slopes of a conspicuous, extinct volcano over 8,000 feet high. A large pebble beach forms the shore of a small cove at the head of the bay, and the northern shore is formed by rock cliffs and deep valley glaciers. The bay may be naviga- CONFIDENTIAL - Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY-JANUARY 1956 MILITARY GEOGRAPHY ble, depending on the condition of the pack ice and on swell which enters the bay from the south- east. Most of the south side of Wood Bay is backed by the slopes of Mt. Melbourne, and the other sides are backed by mountain peaks and ridges between which glaciers flow from the high interior plateau. A landing was made near the head of Wood Bay in 1900 by members of Borch- grevink's Expedition (landing place (40) ) . Northward of Wood Bay is a large indentation which extends about 50 n. miles westward into the coast. The shores of the embayment are backed by high mountains up to about 4,000 feet high. Except for a small inlet in the northeastern part, the embayment is completely filled by an ice shelf. The shelf ice probably varies in shape and size from year to year but the dimensions are now about 58 n. miles long north - south by 50 n. miles wide and the seaward edge is about 20 to 150 feet high. A group of small islands lie in the shelf ice near its southern end. Coulman Island, about 18 n. miles long and 9 miles wide, lies to the east of the ice shelf. The island, flat on top, rises near the northern end to a low dome about 2,000 feet high. It is completely snow-covered except at the shore which is formed by cliffs about 500 to 1,500 feet high. A channel separates Coulman Island from the eastern edge of the shelf ice but this channel has not been explored by ships. Pack ice which breaks out of bays and inlets farther south drifts northward along the face of the shelf ice and becomes congested near Coulman Island, which may in some years, keep the area ice-filled -until February. An inlet which extends into the northern end of the shelf ice for about 16 n. miles is accessible to ships. Landings have been made on the ice inside the inlet (landing place (41) ) in the shelf ice and on some rocks at the base of the cliffs at the north end of Coulman Island (landing place (42) ) . The shore along the coast from landing place 41 northward to Cape Adare rises in steep rocky bluffs and cliffs broken in places by ice slopes which extend down to the sea from the icecap, and is backed by the high mountains of Victoria Land. Possession Islands, a group of 9 volcanic islands and islets, lie about 1 n. mile to 3 n. miles offshore. The islands range in size from about 3 miles long to mere pillars of rock with vertical walls as much as 300 feet high. The northwestern island, about 3 miles across and the largest of the group, is low and bare except for a small peak about 300 feet high at the southeastern extremity. The other islands are rocky and most of the shores are formed by cliffs. The channel between the islands and the mainland has been passed by several ships and is believed to be free of dangers, however, heavy pack ice may block this channel. CONFIDENTIAL CONFIDENTIAL Landings were made by Ross in 1841, by Kristen- sen in 1894, by Borchgrevink in 1899 and by Col- beck in 1903, on a long stony beach on the south- western side of the largest island in the group (landing place (44) ). Scott Island, lying about 315 n. miles northeast- ward of Cape Adare, is a rocky ice-covered islet about 500 yards long in a north - south direction and about 250 yards wide. The sides are mostly cliffs, high on the north end and sloping gradually to the southern end where they are about 6 feet high. A landing was made in 1902 on the south- eastern side of Scott Island by members of the British Colbeck Relief Expedition (landing place (43) ) . F. Coastal Sector 4: Cape Adare to Cape Adams 71?S., 170?E.; 75?S., 62?W. (FIGURE 22-76; USHO Charts 6636, 6640, 6641, and 16321-9; B.A. Charts 3171 and 3172) 1. General Coastal Sector 4 is composed of the Antarctic coast lying west of the Ross _Sea and east of the Palmer Peninsula. Cape Adare is the eastern limit of the sector and Cape Adams is the western limit. The Indian Ocean and the South Atlantic Ocean border, the coast of the sector, which measures about 5,990 miles in length. The approaches to most coasts of the sector are obstructed by a broad belt of pack ice that in places lies as far as about 1,000 n. miles offshore. The difficulty in transiting the belt of pack ice is usually least in January and February, and least along certain meridians such as the Green- wich meridian, and between about 70? and 90?E. Between the belt of pack ice and the mainland, broad areas of navigable water usually prevail. A strip of land ice, fringed by sea ice, immediately borders most shores, making the depths in the water adjacent to the ice relatively great. -In those, areas where vessels may apprOach ice-free parts of the mainland, or close-lying ice-free islands, the chief navigational danger is the possibility of run- ning aground on uncharted rocks and pinnacles, which seem to abound in such areas. Near most of the ice-free areas the depths and bottom con- tours are usually quite erratic. The Balleny Islands lying about 150 n. miles offshore near the east end of the sector, and sev- eral scattered islands off the Queen Mary Coast in the vicinity of 90? to 105?E., are the main larger islands in the sector. Many widely spaced groups of small islands, however, border the coast. The small islands, where bordered by a. relatively narrow width of sea ice, often constitute the most accessible land. In places such as the Vestfold PAGE 22..850X1 _ Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL N I S 6 9 NAVY - JANUARY 1956 Hills along the east coast of Prydz Bay (about 77?E.), ice-free hills separated by inlets usually afford landing places. Similar areas that are usually ice free lie along the east coast of Vin- cennes Bay (110?E.) , close east of Denman Gla- cier (100?E.) , and southeast of Stefansson Bay (59?E.), but the approaches to these areas are at times obstructed by ice. Except for these ice- free areas, and the ice-free headlands and out- crops along the coast, nearly all coastal terrain is covered by continental ice. In many places in the interior, however, ice-free mountain peaks penetrate the continental ice. In Coastal Sector 4 a small number of landings have been made at rather widely spaced places. In general these landings are grouped in the vicin- ity of 140?E., and between 500 and 110?E. The chief factor governing the location of landing sites is the navigabilityi of the adjacent seas, as con- trolled by the character or absence of ice. 2. Coast and landing places Between Cape Adare and Cape North, about 100 n. miles to the northwest of Cape Adare,, the coast is composed of steep rocky cliffs and headlands sep- arated by glaciers with Cliffed faces. This stretch of coast is usually inaccessible to vessels because of the belt of drift ice and icebergs that usually borders the shore. A bay and several fjord-like inlets indent the shore. The largest and easternmost bay, Robertson Bay, opens about 20 n. miles and is indented about 24 n. miles to the southeast. About one-half mile south of Cape Adare a triangular spit about 1 mile in extent provides the only landing place in the bay. This landing place (landing place (45) ) was used by Kristensen . and Bull in 1894-95, by Borchgrevink in 1899, and by the northern party of the Scott expedition in 1912. The remaining shores of Robertson Bay are composed largely of steep cliffs and headlands separating glaciers and glacier tongues. Anchorage may be taken almost any place on the east shore of the bay where the holding ground is good. There is a paucity of soundings in the bay, but the large number of grounded bergs observed indicates comparatively shallow water near the eastern shore. Because of ice carried into the bay by strong currents and frequent gales, vessels should keep engines in readiness at all times. Between Robertson Bay and Smith Inlet, about 45 miles to the northwest of Robertson Bay, the coast consists of steep rocky cliffs and headlands and the cuffed margins of glaciers. Smith Inlet, which appears to be a fjord, is about 8 n. miles wide and recedes inland a considerable distance. Yule Bay, about 6 n. miles wide and indented a similar distance, 'lies about 19 miles northwest of PAGE 22-82 Smith Inlet. Cape North, a vertical snow-covered cliff over 200 feet high, is about 22 miles westward of Yule Bay. The entire stretch of coast is backed by the mountains of the Admiralty Range. The Balleny Islands lie about 150 n. miles off Antarctica between 162? and 165?E. longitude. The sea between the islands and the mainland is frequently covered by heavy, impenetrable pack ic'e. The islands, volcanic in origin, consist of three large and two small islands which extend north- west and southeast for about 100 n. miles. The islands are heavily glaciated With ice tongues pro- jecting into the sea, and the shores are mostly steep with rock or ice cliffs. Sturge Island, the largest and southeasternmost of the Balleny Islands, is about 32 miles long and 10 miles wide. Most of the shore is formed by rocky cliffs and broad ice tongues. Buckle Island, about 15 miles long in a general north ? south direction and 3 miles wide, lies ap- proximately 30 n. miles northwest of Sturge Island. The island is composed of a gently sloping plateau about 3,000 feet high, ending at the shore in steep rock or ice cliffs. Several rocks and islets, the largest of which is Sabrina Islet, lie about 2 n. miles off the southern extremity of Burke Island. Young Island, the northeastern island of the group, is about 24 miles long and 6 miles wide. The island terrain slopes gently seaward from a 'plateau about 3,250 feet high. The northern and southern ends of the island are steep rocky bluffs, and the western side is steep and crevassed, but low. Rocks about 50 feet high lie off the northern end of the island, with foul ground extending for a distance of about 2 n. miles seaward. Two small islands lie off the southern end of Young Island. The largest, Borradaile Island, about 21/2 miles long and 1 mile wide, is ice-capped, about 1,250 feet high, and the shores are composed mostly of rock cliffs. An Australian expedition led by Stuart Camp- bell landed on Borradaile Island in 1948 (landing place (47) ). Another landing was made on Bor- radaile Island in 1839 by Captain Freeman of the ? cutter Sabrina, which accompanied Captain Bel- lany's schooner Eliza Scott to the area. Members of a French expedition in 1949 landed on Sabrina Islet (landing place (46) ). From Cape North to Cape Freshfield, the coast trends in a west-northwesterly direction a dis- tance of about 390 miles. This part of the coast, and some of the polar plateau behind it, has been seen from the air, a few areas have been observed from the sea, but none have been explored. Lillie Glacier Tongue projects northward for about 20 n. miles between Cape Williams, about 60 n. miles west-northwest of Cape North, and Cape Cheet- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY - JANUARY 1956 MILITARY GEOGRAPHY ham, about 22 n. miles farther westward. The coast between Cape Cheetham and Cape Kinsey, about 110 miles northwestward, has not been ob- served from the sea. The coast between Cape Kinsey and Archer Point, about 20 miles west- northwest, is rugged and the shore is made up mostly of steep rocky points separated by glaciers and backed by high hills. Between Archer Point and Cape Freshfield, about 160 miles west-north- westward of Archer Point, the only part of the coast that has been observed from the sea is a 50-mile stretch of the shores of Joseph Cook Bay. Between Cape Freshfield and the east edge of Ninnis Glacier about 90 miles to the west (148?E.) , the coast is composed of hilly to mountainous ter- rain, most of which is covered by snow and ice. A bluff about 28 n. miles west of Cape Freshfield rises almost vertically for about 1,000 feet, capped by about 200 feet of snow. The bluff is composed of columns of red rock overlying horizontal strata that crops out near the top of the 300-foot-high slopes of rock debris that conceal the base of the bluff. About 10 miles west of Cape Wild, which lies about midway along this stretch of coast, cliffs of columnar rock lie along the coast and continue southwestward for an additional 10 miles. In sev- eral places between the areas of columnar rock cliffs, small embayments deeply indent the coast. At the west end of this stretch of coast Buckley Bay is enclosed on the west by Ninnis Glacier, which extends almost 80 n. miles seaward as a glacier ice tongue. Most of this stretch of coast was surveyed in 1912-13 by a sledge party from the Australasian Antarctic Expedition based in Commonwealth Bay to the west. Ninnis Glacier and Mertz Glacier enclose a large bay that was entered in 1840 by Wilkes' ship, the Vincennes. Measured along the coastal trend the bay is about 55 miles wide, and including the glaciers the coast measures about 120 miles in length (to 144?30'E.) . Most of the coast of the bay consists of ice cliffs, behind which rise ice-covered slopes that teach elevations of about 3,000 feet about 20 to 25 miles inland. For about 5 miles along the coast 'of the west half of the bay, a rock outcrop about 300 feet high underlies the icecap. Both Ninnis Glacier to the east and Mertz Glacier to the west have heavily fissured surfaces, and both terminate in glacier tongues facing the sea with ice cliffs standing 100 to 180 feet high. Mertz Glacier, which extends about 50 n. miles seaward, descends from the high interior plateau through a steep-walled valley. West of Mertz Glacier to Point Alden, about 75 miles to the west-northwest (142?E.) , the coast con- sists of three embayments separated by capes bor- dered by reefs and islets. The two capes are bordered by ice cliffs, but at the head of the middle CONFIDENTIAL CONFIDENTIAL embayment the elevation of the shore decreases almost to sea level and a valley extends inland. The western embayment, Commonwealth Bay, con- tains a number of islets and reefs, and in most places is bordered by ice cliffs 60 to 150 feet high. During the summer months the strong southerly winds usually keep the bay clear of pack ice. A cape at the head of the bay, which was the site of the main base of the Australasian Antarctic Expedi- tion (1911-14) of Sir Douglas Mawson, rises about 40 feet above sea level (landing place (48) ). Near the cape, a landing was made in a small cove that was about 300 yards wide and 1,000 yards long, with depths of about 15 feet. The cape was again landed upon in 1931 by Mawson's British-Austral- ian-New Zealand Antarctic Research Expedition, and again in 1950 when the French Antarctic Ex- pedition laid a depot there. About 8 miles west of the cape, another rocky cape rises about 80 feet above the sea and is off-lain by reefs and an islet. About 10 miles northwest of the second cape, Point Alden marks the western entrance point to Com- monwealth Bay. The boundary between George V Coast on the east and Adelie Coast on the west lies near Point Alden. From Point Alden to Cape Robert (138?E.), the slightly irregular coast measures about 125 miles in length. This stretch of coast was viewed by Wilkes in 1840, and landed upon by D'Urville. The latter expedition sighted a cape about 12 miles west of Point Alden, but was unable to land because of pack ice. The expedition successfully landed men among the islands near Astrolabe Glacier, however, which lies above 70 miles west of Point Alden (land- ing place (51) ). About 17 miles west of Point Alden, the French Antarctic Expedition in 1950 landed and made their base camp (landing place (49) ) . The expedition also laid a depot on the coast a short distance east of Cape _Bienvenue be- tween Point Alden and Astrolabe Glacier (landing place (50) ). Between Point Alden and Cape Robert the coast is bordered by groups of small islands that serve as rookeries for Antarctic birds. Access to the main- land in most places is obstructed by ice cliffs that are breached in places by glaciers that extend 2 to 5 n. miles seaward. Back of the ice cliffs the inland ice rises toward the interior and reaches elevations of about 2,500 feet about 15 to 18 miles inland. From Cape Robert to Cape Folger, the coast ex- tends westward about 785 miles. From the vicinity of Cape Robert, westward about 195 miles to Cape Mose (130?E.) , the coast is usually bordered by pack ice extending as much as 60 to 80 n. miles off- shore. The ice commonly contains icebergs which may drift into the pack on the prevailing ocean cur- rents. This stretch of coast, most of which lies 50X1 PAGE 22-83 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 within the limits of the Clarie Coast, has been de- scribed as being composed of high, snow-covered hills. The Banzare Coast, named after the British- Australian-New Zealand Antarctic Research Ex- pedition Of 1929-31, extends west from Cape Mose , to 122?E. and measures about 170 miles in length. Porpoise Bay, which indents the coast between Cape Mose and Cape Goodenough (126?E.) , was named after one of the vessels of the Wilkes expedi- tion of 1840. The bay, whose limits are not de- fined, is about 85 n. miles wide and recedes south- ward about 50 n. miles. From the Banzare Coast, west to Cape Folger (110?30'E.) , the coast meas- ures about 335 miles in length. This stretch of coast includes the Sabrina Coast (approximately 116? to 122?E.) and, at the western extremity, the Budd Coast (approximately 110? to 116?E.). In the past, access to most of this coast has been denied by a wide area of pack ice containing im- prisoned icebergs. In 1840 when Wilkes' ship lay 35 to 40 n. miles offshore, he reported the Budd Coast as composed of a lofty, snow-covered moun- tain range trending nearly east and west, and show- ing many ridges and indentations. From Cape Folger to Cape Elliott, the coast ex- tends generally westward about 246, miles. Vin- cennes Bay lies immediately west of Cape Folger. The bay is about 66 n. miles wide between the east- ern entrance point, Cape Folger, and the western entrance point, Cape Nutt (108?20'E.) , and is in- dented about 30 n. miles. A group of islands lies in the eastern part of the bay near Cape Folger (FIGURE 22-54C) and another group in the western part of the bay near Cape Nutt. In 1948 a party from U.S. Navy Task Force 39 landed by boat on the islands in the east part of the bay (landing place (52) ) . Their ship reported depths of 45 fathoms 800 yards offshore, and depths of 800 fath- oms about 1 n. mile offshore. Several glaciers dis- charge along the head and east coast of Vincennes Bay. From Cape Nutt, the western entrance point to Vincennes Bay, the coast trends west-northwest to Cape Elliott (103?E.) , a distance of about 170 miles. All of this coast is part of the Knox Coast, which was viewed by Wilkes in February 1840. Wilkes described the coast as high, rounded in form, and terminating in vertical ice cliffs. Bowman Island, covered by ice and about 17 miles long, lies about 30 n. miles northeast of Cape Elliott. Pack ice usually extends 40 to 60 n. miles off this coast and to the westward merges with Denman Glacier and the Shackleton Ice Shelf. In 1948 a party from the U.S. Navy Task Force 39 made a helicopter land- ing on a small islet lying close offshore about 37 miles west-northwest of Cape Nutt (landing place (53) ) ? PAGE 22-84 NAVY - JANUARY 1956 From Cape Elliott, west-southwest about 200 miles to Farr Bay (95?E.) , the coast is continuously fronted by ice that at times extends 200 n. miles seaward. All except the eastern part of this stretch of coast is bordered by the Shackleton Ice Shelf which might extend as much as 120 n. miles out to sea. The shelf ice, which encompasses many is- lands, extends westward from Denman Glacier which lies about 90 miles from Cape Elliott. Den- man Glacier is the largest of the many glaciers. along this stretch of coast. The glacier usually terminates at sea in ice tongues that at times reach as much as 45 n. miles seaward. Flanking Denman Glacier about 25 to 50 miles inland are mountain peaks at elevations of approximately 4,000 feet. The coast between Cape Elliott and Denman Glacier was landed upon by helicopter in 1948 by men of the U.S. Navy Task Force 39 (landing place (54) ) . Most of the area landed upon was composed of hills with a maximum of 400 feet of relief, and covered by glacial material (FIGURE 22-55A). Nearly all ponds and inlets in the area were found to contain salt water. The coast west of Denman Glacier was explored in 1912-13 by men of Maw- son's Australasian Antarctic Expedition. The base for this group of men was located on the Shackleton Ice Shelf near Farr Bay (landing place (57) ) . Par- ties from the U.S. Navy Task Force 39 in 1948 landed by boat on islets near the Shackleton Ice Shelf (landing place (56) ) , and by helicopter on islets protruding through the shelf ice (landing place (55) ) . All eicept the eastern extremity of this entire stretch of coast is part of the Queen Mary Coast (92? to 100?E.). From the east edge of Farr Bay, west about 215 miles to Cape Penck (about 88?E.) , most of the coast is bordered throughout the year by at least a narrow belt of sea ice. At the west end of the coast, however,' Cape Penck is encircled by the West Ice Shelf which in that immediate vicinity ex- tends about 40 n. miles offshore. The coast be- tween Farr Bay and Cape Penck is bordered by)the Davis Sea which is usually navigable during the Antarctic summer. The approaches to the sea, however, are often encumbered by pack ice, es- pecially off the Shackleton Ice Shelf, but ships usu- ally are able to reach the Davis Sea by approaching from the north along the 90? meridian. Drygalski Island lies about 45 n. miles off the mid-portion of this coast. The island is about 9 miles in diameter and rises to an elevation of about 1,200 feet, but is completely covered by ice and is encircled by sheer ice cliffs. Depths of 65 to 100 fathoms have been found close off the island. A small number of islands and islets lie close off the mainland. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY - JANUARY 1956 MILITARY- GEOGRAPHY A landmark along the coast is Gaussberg, an ex- tinct volcano that rises to an elevation of about 1,148 feet about 48 miles east of -Cape Penck. The mountain, pyramidal in shape and in places bare of snow and ice, stands close back of the shore. A landing by Drygalski's German Antarctic Expedi- tion of 1901-3 was made near Gaussberg (landing place (62) ) , though their ship, the Gauss, wintered in the ice about '50 n. miles offshore. In 1948 par- ties from the U.S. Navy Task Force 39 landed at four places along the coast between Farr Bay and Gaussberg (landing places (58) through (61)). Two of the landings, made to points above the ice cliffs, were accomplished by helicopter; one landing on sea ice near the coast was accomplished by heli- copter; and one landing on an island was accom- plished by traversing the sea ice in a "Weasel." Between Cape Penck and Cape Darnley (69?30'E.), about 450 n. miles to the west-south- west, the coast is indented about 190 n. miles by a broad embayment. Several stretches of the em- bayment coast are free of the usual cover of con- tinental ice and have been landed upon by several expeditions. The waters close off the coast are often free of critical pack ice, though about 100 to 300 n. miles from shore the ice conditions are com- monly much worse. A reef of doubtful existence has been charted about 105 n. miles northeast of Cape Darnley. For a distance of about 50 n. miles northeast of the cape, Icebergs often become stranded and cause congestion of the ice pack. The West Ice Shelf, which in most places ranges from about 10 to 20 n. miles in width, borders the coast for about 230 miles southwest from Cape Penck. This stretch of coast constitutes the Leo- pold and Astrid Coast. The remainder of the southeastern coast of the broad embayment meas- ures about 490 miles in length and is called the Ingrid Christensen Coast. Prydz Bay lies off the Ingrid Christensen Coast, between it and the Amery Ice Shelf. The southwestern coast of the broad embayment, most of which is fronted by the Amery Ice Shelf, is called the Lars Christensen Coast. MacKenzie Bay lies to the northwest between the Amery Ice Shelf and the northern part of the Lars Christensen Coast. From the southwestern extremity of the West Ice Shelf, west-southwest about 93 miles to the Vestfold Hills, the coast is covered by continental ice that at sea terminates in ice cliffs. The continental ice is heavily crevassed near the ice front, but is es- sentially featureless toward the interior. From the ice cliffs the rate of ascent toward the interior is at first comparatively rapid (about 5 feet per 100 feet) , but shortly levels off to an imperceptible rise toward the interior ice plateau. CONFIDENTIAL CONFIDENTIAL Sotithwestward of the ice cliffs the ice-free Vest- fold Hills straCh about 28 miles along the coast, and extend inland a maximum of about 14 miles. The hill area is fronted by scattered islands and perhaps by scattered reefs, and is intruded by in- lets and fjords (FIGURE 22-55B) . The hills, which rise to maximum elevations of about 425 feet, are steep-sided on most lower slopes. The hills are composed of bedrock intruded by dikes, and in a few places are lightly covered by morainal material. The hills reach their highest elevations near the center of the group, but toward the interior the elevations decrease. Along the inner margin of the hills the edge of the continental ice near sea level rises in ice cliffs, but on the hillsides gradually thins to a low, morainal ridge. Back of the hills the continental ice gradually rises to the high interior plateau the same as the continental ice to the northeast. The Vestfold Hills area was landed upon in 1935 by Captain Mikkelsen of the Nor- wegian Lars Christensen expedition, and in 1939 by men of Ellsworth's expedition (landing place (63) ) . Southwestward from the Vestfold Hills to the head of Prydz Bay, a distance of about 140 miles, the coast is bordered by glacier ice tongues sepa- rated in places by ice-free hills and in places is off- lain by groups of ice-free islands. The glacier tongues range in width from about 9 miles in the SOrsdal Glacier ice tongue adjacent to the Vest- fold Hills (FIGURE 22-56A) , to about 35 miles in the multiple tongues that make up the Publication Ice Tongues about 78 miles to the southwest. Of the island and hill areas, which range in width from 12 to 29 miles, the Rauer Islands and the Larse- mann Hills make up the most conspicuous areas (FIGURE 22-56B) . In 1939, men of Ellsworth's ex- pedition landed on some of the ice-free islands of this area (landing place (64)). In general, each ice-free area is very roughly comparable to the Vestfold Hills in composition, height, and appearance. Like the Vestfold Hills, along its landward margin each island and hill area is overlain by the edge of the continental ice which terminates in moraines and ice cliffs. Toward the interior the continental ice gradually rises to the ice plateau of the interior, reaching elevations of about 7,700 feet above 100 miles inland, and higher elevations farther inland. In two known areas, however, the continental ice rises as much as 1,500 feet in the first mile from the sea. Near the southwest end of this coast one of the Publication Ice Tongues extends about 20 to 40 n. miles into Prydz Bay, almost reaching to the Amery Ice Shelf on the opposite side of the bay. The two opposing ice formations constrict the entrance to a bay which lies to the southwest and is probably covered with ice almost every summer. Scattered islands border the southeastern shores of the bay PAGE 22-50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 and Baker Three Glacier discharges into the head of the bay. The Amery Ice Shelf extends about 60 to 70 n. miles north-northwest from its near juncture with the Publication Ice Tongues. At least part of the terrain behind the ice shelf is mountainous. Mac- kenzie Bay, which lies to the northwest of the Amery Ice Shelf, is almost entirely bordered by ice cliffs. Nevertheless, landings were made at the head and along the western shore of the bay by men of Lars Christensen's ship, the Torlyn, in 1931 (landing places (65) and (66) ) . From Cape Darnley, westward about 135 miles to Cape Daly (64?30'E.), most of the coast is bordered by ice cliffs, but landings have been made in two places near the middle of this stretch of coast. In approaching this coastal stretch, vessels should at- tempt to make a landfall well to the eastward, and then work westward. The approaches to the east- ern half of this coastal stretch are reported as clear, except for the tendency of icebergs to become stranded within 50 n. miles northeast of Cape Darnley and cause congestion of pack ice. Several rocks and reefs are charted in the approaches to the west half of the coast, and it is reported that many rocks and submerged pinnacles are uncharted. Foul ground is reported about 45 n. miles northeast of Cape Daly. Near the middle of this stretch of coast, two huge rock masses lying about 4 miles apart rise steeply from the waters edge. Several uncharted reefs are reported to lie in the near vicinity. The eastern rock mass, Murray Monolith, rises sheer about 1,250 feet above the sea and the western rock mass, Scul- lin Monolith, rises to an elevation of about 1,550 feet. Several expeditions have made landings near Murray Monolith (landing place (67) ) . A landing has also been made near the scree-strewn slopes of Scullin Monolith, and a cache of supplies been deposited there (landing place (68) ) .? ? Along the western two-thirds of this stretch of coast scattered mountain peaks that reach eleva- tions of about 1,500 to 3,300 feet penetrate the con- tinental ice at distances of about 3 to 20 miles from the shore. All of this stretch of coast is part of the Mac-Robertson Coast, which continues farther to the west. Between Cape Daly and Austnes Point (57?20'E.), the northern entrance point of Edward VIII Bay, the coast measures about 220 miles in length. This stretch of coast is bordered by groups of is- lands and islets which during the summer are usu- ally free of show and ice, and often ar6 joined by sea ice. Though open water is commonly found a short distance off the coast, at times northerly swell and west-setting currents press pack ice and ice- bergs in toward the shore. To the north, however, between about 62? and 66?S., pack ice often impedes PAGE 22-86 NAVY - JANUARY 1956 the approach to the open water nearer the shore. Ships usually find the easiest route of approach to lie between about 70? and 80?E., by-passing the area of pack ice and approaching the coastal seg- ment from the east. The east half of the coast is part of the Mac-Robertson Coast, and the west half comprises the Kemp Coast. The groups of islands along this coast extend a maximum of about 20 n. miles offshore, and are surrounded by widely ranging depths. Most of the islands range in height between 100 and 400 feet, and some of the larger ones are dotted with fresh water lakes. When clear of ice the small bay lying about 87 miles southeast of Austnes Point, adjacent to S tefansson Bay, may afford shelter for vessels and the shores may afford landing places. In 1933 the British Discovery Investigations expedition landed and investigated the bay (landing place (70)). Most of this stretch of coast is bordered by ice cliffs, interrupted in places by high rock cliffs, most of which are about 600 to 1,200 feet high. In places, however, heavily crevassed icefalls overlie the cliffs and, especially along the Kemp Coast, ice- free hills are separated by tongues of continental ice that at sea end in ice cliffs. The coast between about 25 and 55 miles west of Cape Daly is backed by ranges of north ? south trending ridges that rise about 5 to 10 miles inland, and are charted as, far south as about 40 miles inland. The ridges, which make up the Framnes Mountains, rise to about 3,000 to 5,000 feet in elevation. Farther to the west, scattered peaks show through the con- tinental ice. In 1931 Mawson's British-Australian- New Zealand Antarctic Research Expedition landed at a point about 95 miles west of Cape Daly (land- ing place (69)). Between Austnes Point and the head of Ice Bay (49?30'E.), the coast measures about 290 miles in length. Most of this stretch of coast is fronted by ice cliffs but near the northernmost part of the coast, small groups of islands that in the summer are free of ice lie in front of the cliffs. The largest of these islands, Proclamation Island, rises to about 800 feet and was landed upon in 1930 by the Brit- ish-Australian-New Zealand Antarctic Research Ex- pedition (landing place (71)). Pack ice that is an- chored by these islands and by grounded icebergs, and is held ashore by winds and swell, obstructs the approaches to much of this coast. The approaches to the western part of this coastal stretch and to Ice Bay are perennially obstructed by ice. In 1929, men from the Norwegian Lars Christensen expedi- tion ship Norvegia, under Captain Riiser-Larsen, landed by airplane on the sea ice near Cape Ann, about 90 miles west-southwest of Proclamation Island (landing place (72) ) . The interior of En- derby Land is covered by the continental ice sheet. CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? NAVY-JANUARY 1956 MILITARY GEOGRAPHY Mountain peaks, most of which reach elevations of about 1,500 to 2,000 feet, pierce the icecap within about 20 miles of the sea. Farther inland the peaks and mountain ranges rise to higher elevations. Between Ice Bay and Riiser-Larsen Peninsula (34?E.), the coast measures about 290 miles in length. Most of this stretch of coast is bordered by ice cliffs that have been perennially unapproach- able because of the pack ice, which may be held ashore by northerly swell. Most of the coast has been viewed only from an airplane. In the bay im- mediately east of the Riiser-Larsen Peninsula, many islands border the east coast, which is made up of many rocky headlands. Between the head of this bay and Ice Bay to the east, the inland ice rises in steep slopes which contain countless nuna- taks and peaks. This stretch of coast is the Prince Olav Coast. To the south of the bay, mountains that are usually ice-free in the summer protrude through the inland ice. The west coast of the bay is the Prince Harald Coast. The coast extending about 780 miles westward from the northwestern extremity of the Riiser- Larsen Peninsula to about 5?E., makes up the Prin- cess Ragnhild Coast and the Princess Astrid Coast. The Riiser-Larsen Peninsula is covered by ice and is devoid of nunataks and outcrops. The entire stretch of coast is bordered by ice cliffs and in places, notably along the western part of the Prin- cess Astrid Coast, the ice cliffs contain many in- dentations. Rugged mountains 6,000 to 10,000 feet high lie about 75 miles inland along most of the Princess Ragnhild Coast. Mountain peaks from 10,000 to 13,000 feet high lie about 100 miles inland along the Princess Astrid Coast. In 1933 a sledge party from a Norwegian expedition under Captain Riiser-Larsen landed somewhere on the Princess Ragnhild Coast' (landing place (73) (position in- definite) ). In 1939 a party from the German Ant- arctic Expedition under Captain Ritscher landed near the western limit of the Princess Astrid Coast (landing place (74) ) . The Princess Martha Coast, about 540 miles in length, lies west of the Princess Astrid Coast be- tween about 5?E. and 20?W. Most of the Princess Martha Coast is bordered by ice cliffs, though three short stretches lying west of the Greenwich me- ridian are free of ice cliffs. During the early part of the summer a belt of pack ice lying in the vi- cinity of the 60?S. parallel obstructs the approach to the Princess Martha Coast, though south of the belt of ice the seas are usually navigable. The belt of pack ice usually .disappears in late December and early January. The route of approach that best minimizes the barricade of pack ice lies along the Greenwich meridian. CONFIDENTIAL CONFIDENTIAL The Princess Martha Coast lying east of the Greenwich meridian is entirely fronted by ice cliffs, behind which snow-covered nunataks pierce the continental ice. Astride the Greenwich meridian, an ice tongue about 25 to 45 n. miles wide extends about 70 n. miles seaward, with depths of about 1,000 fathoms at the se,award extremity. Along the west sideof the ice tongue a broad rift open- ing about 21/2 n. miles has been named Byrd Bay (FIGURE 22-57A) . Toward the interior the bay narrows, and about 5 n. miles from the entrance is covered by bay ice. In 1955 the U.S. Navy ice- breaker Atka tied up to the bay ice (landing place (75.)') (FIGURE 22-57B) . West of the broad ice tongue the coast is bordered by ice cliffs, except for three comparatively short stretches along the ends of projecting peninsulas. Near the first peninsula the German Antarctic Ex- pedition of 1938-39 landed in two places (landing places (76) and (77) ). About midway between the first and second breaks in the ice cliff, Atka Bay indents the ice cliff about 7 n. miles (FIGURE 22-58A) . In places around the bay the ice cliffs are only about 15 feet high, so probably can be landed upon. Men from the U.S. Navy icebreaker Atka were transported to the top of the ice cliff by helicopter (landing place (78) ) . Along the sec- ond break in the ice cliff the Norwegian-British- Swedish Antarctic Expedition of 1949-50 landed and set up their base, Maudheim (landing place (79) ) . A short distance west of the third break in the ice cliff, which extends both east and west from Cape Norvegia, men from the Atka also made a landing (landing place (80) ). The terrain backing the Princess Martha Coast is characterized by snow-covered slopes, many 'of them so precipitous as to be snow-free, and rising to altitudes reportedly greater than 13,000 feet. That part of Coats Land lying between the Prin- cess Martha Coast and Duke Ernst Bay (35?W.), which measures about 385 miles in length; faces the Weddell Sea in an almost continuous ice cliff. During the early summer months pack ice lying about 700 to 1,000 n. miles offshore obstructs the approaches to the coast, though navigable seas im- mediately border the coast. The eastern 100 miles or more of this stretch of coast is bordered by shelf ice. To the west the suc- ceeding 45 miles of coast is unsUrveyed. Most of the remainder is bordered by shelf ice, interrupted in several places by broad glaciers terminating in very high cliffs. Soundings of 80 fathoms or more have been taken a short distance off the ice front. These comparatively shallow soundings, plus evi- dence of tide marks on the ice, indicate that the glacier ice is not afloat. PAGE 22-50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 From Duke Ernst Bay to Cape Adams, the coast, which is fronted completely by the Filchner Ice Shelf, trends northwestward about 425 miles to Cape Adams (75?04'S., 62?20'W.). The treacher- ous ice of the Weddell Sea prevents approach to the coast, except during the summer season when some penetration from the east is possible. At the head of Duke Ernst Bay, two glaciers, Schweit- zer Glacier and Lerchenfeld Glacier, descend from the high inland terrain. With a German expedi- tion Filchner landed in this area in 1912, but later abandoned the site (landing place (81) ). The southern entrance point of the bay is marked by Bertrab Nunatak, a bare rock about 1,000 feet high. Except for a rough outline of the face of the Filchner Ice Shelf, the coast between Duke Ernst Bay and Cape Adams is uncharted. The edge of the shelf ice is very irregular as far as Gould Bay, an indentation in the shelf about 100 miles west- ward of Duke Ernst Bay. Gould Bay, about 15 miles across, is indented about 20 miles southward. West of Gould Bay the shelf ice front is compara- tively regular. The interior, called Edith Ronne Land, is completely uncharted. G. List of sources In addition to standard intelligence sources such as the Special NIS, Sailing Directions, Tide Tables, and NIS Antarctica Gazetteer, are the following: 1. ARCTOWSKI, HENRYK, AND MILL, H. R. "Oceano- graphie, relations thermiques; rapport sur les ob- servations thermometriques faites aux stations de sondages" (Oceanography, thermal relations; re- port of thermometer observations taken at sound- ing stations) , Expedition Antarctique Beige, Resul- tats du Voyage du S. Y. BELGICA en 1897-1898-1899, Rapports Scientifiques, tome 5, partie 3, p. 16-19, 24-36, 1902. 2. ARCTOWSKI, HENRYK, AND THOULET, J. "Oceano- gra,phie; rapport sur les densites de l'eau de mer observees a bord de la Belgica" (Oceanography.; report on sea water densities observed on board the BELGICA), Expedition Antarctique Beige, Resultats du Voyage du S. Y. BELGICA en 1897-1898-1899, Rapports Scientifiques, tome 5, partie 3, p. 20-22, 1902. 3. ARGENTINA, DIRECCION GENERAL DE NAVEGACION E HIDRO- GRAFIA DEL MARINA. 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The Great White South. London: Hazell, Watson, and Viney, Ltd. 1932. 305 p. 113. POWERS, M. R., ROCHE, K. A., AND ONYX, P. M. "Con- tours of Transmission Loss for Standard Conditions and Correction Charts," U.S. Navy Underwater Sound Laboratory, Technical Memorandum No. 1110-101-54. 1954. 66 p. 114. PRIESTLEY, R. E. "Physiography; Robertson Bay and Terra Nova Bay Regions," British Antarctic (Terra Nova) Expedition, 1910-1913, London: Harrison and Sons, Ltd. 1923. 87 p. 115. REICHELT, WERNER. "Die ozeanographischen Verhalt- nisse bis zur wormen Zwischenschicht an der antarktischen Eisgrenze in Siidsommer 1936-1937, nach Beobachtungen auf dem Walfangmutterschiff JAN WELLEM im Weddell-Meer" (Oceanographic conditions down to the warm intermediary layer along the Antarctic ice edge in the southern sum- mer 1936-1937, according to observations on the whaling mother ship JAN WELLEM in the Weddell Sea) , Deutschen Seewarte, bd. 61, nr. 5, p. 1-55, 1941. 116. RIGGI, A. E. ."La Antartida Argentina; Su Geografia y su Geologia" (The Argentine Antarctic; its geog- raphy and its geology) , Buenas Aires, Instituto Nacional de Investigaciones de las Ciencias Natu- rales, Publicaciones de Extension Cultural y Di- dactica, No. 4, p. 1-367;1950. 117. ROBINSON, M. K., COCHRANE, J. D., AND BURT, W. V. "Analysis and Interpretation of Bathythermo- grams from the Antarctic Development' Project, 1947-1948," Scripps Institution of Oceanography, Technical Report. ,La Jolla. 1950. 40 p. 118. RONNE, FINN, AND NICHOLS, R. L. "Preliminary Re- port on the Geology of the Marguerite Bay Area, Antarctica," Ronne Antarctic Research Expedition, Technical Report No. 6, 1948. 8 p. 119. ROSCOE, J. H. Regional Photo Interpretation Series, Antarctica. "Contributions to the Study of Ant- arctic Surface Features by , Photogeographical Methods." 1952. 120. RoucH, JULES. "Observation meteorologiques" (Me- teorological observations) , Deuxi? Expedition Antarctique Frangaise, 1908-1910. Paris. 1911. 260 p. PAGE 22-9:50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69- .121. . "OceanograPhie physique" (Physical Ocea- nography) , Deuxi? Expedition Antarctique Fran- gaise, 1908-10, p. 1-46. Paris. 1913. 122. RUUD, J. T. "Nitrates and Phosphates in the South- ern Seas," Journal du Conseil, Conseil Permanent International pour l'Exploration de la Mer, vol. 5, no. 3, p. 347-360, 1930. 123. . "On the Biology of Southern Euphausiidae," Norske Videnskaps-Akademi I Oslo, Hvalrd dets Skrifter, Nr. 2, p. 1-105, 1932. 124. RYMILL, J. dz. ?`The British Graham Land Expedi- tion, 1934-1937," The Geographical Journal, vol. 91, April, May, June, 1938, and vol. 96, September 1940. London: William Clowes and Sons, Ltd. 84 p. 125. SCHOTT, GERHARD. "Ozeanographie und maritime Meteorologie" (Oceanography and maritime me- teorology) , Wissenschaftliche Ergebnisse der deutschen Tie/see-Expedition auf dem dampfer VALDI VIA, 1898-1899, vol. 1, p. 138-143; 198-207, 1902. 126. . Geographie des Indischen und Stillen Ozeans (Geography of the Indian and Pacific Oceans). Hamburg: C. Boysen. 1935. 413 p. 127. . Geographie des Atlantischen Ozeans (Geog- raphy of the Atlantic Ocean) . Hamburg: C. Boy- sen. 1942. 438 p. 128. . Geographie des Indischen und Stillen Ozeans (Geography of the Indian and Pacific Oceans) . Hamburg: C. Boysen. 1936. Various Pagings. Translated by the Weather Research Center, Di- rectorate of Weather, Headquarters, Army Air Forces. vol. 2, no. 141, 1942. 255 D. ? 129. . "Weltkarte zur iThersicht der Meeresstrom- ungen" (World chart for a survey of sea currents) , Germany, Oberkommando der Kriegsmarine, 1942. 130. SCHULKIN, MORRIS, AND SPONG, R. A. "Lateral Range , Curves for Hull-mounted Echo-ranging Sonars," U.S. Navy Underwater Sound Laboratory, Technical ? Memorandum No. 1110-018-54. 1954. 33 p. 131. SCHULKIN, MORRIS, WHITE, F. S., AND SPONG, R. A. "QHBa Figure-of-merit Tests," U.S. Navy Under- water Sound Laboratory, Report No. 187. 1953. 47 p. 132. SHACKLETON, ERNEST. South: The -Story of Shackle- ton's Last Expedition, 1914-1917. London: William Heinemann. 1919. 376 p. 133. SIMPSON, F. A., ed. The Antarctic Today. Sydney: A. H. and A. W. Reed. 1952. 389 p. 134. SIMPSON, G. C. "Meteorology; Tables," British Ant- arctic (Terra Nova) Expedition, 1910-1913, vol. 3, p. 1-835, 1923. 135. SKTOOSBERG, CARL. "Communities of Marine Algae in Subantarctic and Antarctic waters," K. Svenska Vetenskapsakademien, Handlingar, Tredje Serien, bd. 19, hft. 4, p. 1-92, 1941. 136. SMITH, E. A. "Mollusca; Lamellibranchiata," Na- ational Antarctic Expedition, 1901-1904, Natural His- tory, Zoology, vol. 2, no. 5, p. 1-7, 1907. 137. SMITH, W. C. "The Plutonic and Hypabyssal Rocks of South Victoria Land," British Antarctic (Terra Nova) Expedition, 1910-1913, Natural History Re- - port, Geology,-vol. 1, no. 6, p. 167-227, 1924. 138. . "The Volcanic Rocks of Ross Archipelago," British Antarctic (Terra? Nova) Expedition, 1910- 1913, Natural History Report, Geology, vol. 2, no. 1, p. 1-107, 1934. 139. SMITH, W. C., AND DEBENHAM, F. "The Metamorphic Rocks of South Victoria Land," British Antarctic (Terra Nova) ExpeditiOn, 1910-1913, Natural His- tory Report, Geology, vol. 1, no. 5a, p. 131-144, 1921. PAGE 22-92 NAVY - JANUARY 1956 140. SPEIGHT, ROBERT. "Physiography and Geology of the Auckland, Bounty, and Antipodes Islands," Philo- sophical Institute of Canterbury, vol. 2, p. 705-744, 1909. 141. STETSON, H. C., AND UPSON, J. E. "Bottom Sediments of the Ross Sea," Journal of Sedimentary Petrology, vol. 7, p. 56-66, 1937. 142. STEWART, DUNCAN, JR. "Rocks of the Melchior Is- lands, Antarctica," Proceedings of ?the American Philosophical Society, vol. 91, no. 3, p. 229-233, 1947. 143. SUGIURA, J., AND KUGA, Y. "Report On Sea and Weather Observations on Antarctic Whaling Ground, 1948-1949," Central Meteorological Ob- servatory of Japan, The Oceanographical Magazine, vol. 1, no. 3, p. 142-173, 1949. 144. SVERDRUP, H. U. "On the Vertical Circulation in the Ocean Due to the Action of the Wind with Applica- tion to Conditions Within the Antarctic Circum- polar Current," Great Britain, Discovery Commit- tee, Discovery Reports, vol. 7-, p. 139-170, 1933. 145.. . "The Currents of the Coast of Queen Maud Land," Saertrykk av Norsk Geografisk Tidsskrift, Norsk Polarinstituut, Observatoriegaten 1, bd. 14, nr. 1-4, p. 239-249, 1953. 146. SVERDRUP, H. U., JOHNSON, M. W., AND FLEMING, R. H. The -Oceans; Their Physics, Chemistry, and Gen- eral Biology. New York: Prentice-Hall. 1942. - 1087 p. 147. TAKANO, KENS?. "On the Antarctic Circumpolar Current," Records of Oceanographic Works in Japan, vol. 2, no. 1, p. 71-75, 1955. 148. TAMURA, T., AND SIGIURA, J. "Report On Sea and Weather Observations on Antarctic Whaling Ground, 1947-48," Central Meteorological Observa- tory of Japan, The Oceanographical Magazine, vol. 1, no. 1, p. 56-57; 87-88, 1949., 149. TATTERSALL, W. M. "Arthropoda; Crustacea, Schizo- poda," National Antarctic Expedition, 1901-1904, Natural History, Zoology, vol. 4, no. 7, 1908. 42 p. 150. TAYLOR, GRIFFITH. "Die alten Kerne" (The old core) , Regionale Geologie der Erde, bd. 1, abs. 8, 1940. .34 p. 151. TAYLOR, T. G. Antarctic Adventure and Research. New York: D. Appleton and Co. 1930. 245 p. 152. TILLEY, C. E. "Rocks from Enderby Land," British, Australian, New Zealand Antarctic Research Expe- dition, 1921-1931, (BANZARE), Reports, ser. A, vol. 2, pt. 1, p. 1-16, 1937. 153. . "Rocks from MacRobertson Land," British, ? Australian, New Zealand Antarctic Research Expe- dition, 1921-1931, (BANZARE) , Reports, ser. A, vol. 2, pt. 2, p. 17-26, 1937. 154. TURNER, H. r H., AND OTHERS. International Seismo- ? logical Summary for the Years 1918-1941. Various Pagings. Oxford, England: Oxford University Ob- servatory. 1923-1952. 155. TYRRELL, G. W. "The Petrology of Heard Island," British, Australian, New Zealand Antarctic Re- search Expedition, 1921-1931, (BANZARE), Reports, ser. A, vol. 2, pt. 3, p. 27-56, 1937. 156. . "The Petrology of Possession Island," Brit- ish, Australian, New Zealand Antarctic Research Expedition, 1921-1931 (BANZARE) , Reports, ser. A, vol. 2, pt. 4, p. 57-68, 1937. 157. U.S. AIR FORCE. "Antarctica," U.S. Air Force, Re- gional Photo Interpretation Series, Air Force Man- ual 200-30,1953. 171 p. 158. U.S. BUREAU OF NAVAL PERSONNEL. "Sea and Swell Data Tabulated Only for the Area South of 70?S. from the -Deck Logs of the U.S.S. BEAR." Decem- CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? NAVY?JANUARY 1956 MILITARY GEOGRAPHY ber 1939 through March 1940 and December 1940 through March 1941. Unpublished. 159. U.S. HYDROGRAPHIC OFFICE. Bathythermograph Ob- servations, 1943-1955. Unpublished Data. on File at, the U.S. Navy Hydrographic Office, Division of Oceanography. 160. Fathograms Taken by the U.S.S. ATKA on the U.S. Navy Antarctic Expedition, 1954-1955. Unpaged. Unpublished. 161. . Field Report of Oceanographic Observations of the U.S. Navy Antarctic Expedition, 1954-1955, U.S.S. ATKA, Hydrographic Office Misc. 16333. 1955. 80 p. 162. . "Mean Water Temperatures in ? F. for Mars- den Squares 480-623." Tabulated by the U.S.' Hydrographic Office from H 1-9 Current Report Form Deck for the Years 1904-1945, and by the U.S. Weather Bureau from Weather Bureau Decks: 115 (U.S. Merchant Marine Deck, 1941-1948) ; 116 (U.S. Merchant Marine Deck, 1949-1953) ; 192 (Hamburg, Deutsche Seewarte Deck) ; 193 (Nederlands, Mete- orologisch Instituut Deck) ; 194 (Great Britain Me- teorological Office Deck) ; 195 (U.S. Navy Ships' Logs Observations Deck) ; and 281 (U.S. Navy MAR Synoptic Deck) . Unpublished. 163. . "Sea and Swell Data for Marsden Squares 480-551." Tabulated by the U.S. Hydrographic Office from H 1-9 Current Report Form Deck, and by the U.S. Weather Bureau from Weather Bureau Decks: 115 (U.S. Merchant Marine Deck, 1941- 1948) ; 192 (Hamburg, Deutsche Seewarte Deck).; 193 (Nederlands, Meteorologisch Instituut Deck) ; and 194 (Great Britain, Meteorological Office Deck) . "Additional Sea Data for Marsden Squares 499-514, 533-543." Tabulated by the U.S. Weather Bureau from Weather Bureau Deck: 110 (WBAN 11, U.S. Navy Marine Deck, 1945-1952) ; and from Operation HIGHJUMP, Operation WINDMILL, and Voyage of the ATKA. Unpublished. 164. "Sea and Swell Data Tabulated Only for the Area South of 70?S. from the Deck Logs of the U.S.S. ATKA." December 1954 through April 1955. Unpublished. 165. . "Sea and Swell Data Tabulated Only for the Area South of 70?S. from the Deck Logs of the U.S.S. BURTON ISLAND, U.S.S. CURRITUCK and the U.S.S. PINE ISLAND." December 1946 through March 1947. Unpublished. 166. . "Sea and Swell Data Tabulated Only for the Area South of 70?S. from the Deck Logs of the U.S.S. BURTON ISLAND." December 1947 through March 1948. Unpublished. 167. U.S. NAVY. Report of U.S. Navy Antarctic Expedition 1954-1955. (U.S.S. ATKA, AGB3) . 23 May 1955. 168. U.S. NAVY, COMMANDER TASK FORCE 39. "Report of Operations; SeCond Antarctic Development Project, 1947-1948," U.S. Navy Antarctic Development Proj- ect. 1948. _Unpaged. Unpublished. 169. U.S. NAVY, COMMANDER TASK FORCE 68. "Report of Operation HIGHJUMP," U.S. Navy Antarctic De- velopment Project, vols. 1, 2, and 3, 1947. Unpaged. Unpublished. 170. U.S. NAVY, COMMANDING OFFICER, U.S.S. SENNET (SS 408) . "Report of _ Operation HIGHJUMP, U.S.S. SENNET (SS 408) ," U.S. Navy Antarctic Develop- ment Project. 1947. 75 p. Unpublished. 171. U.S. WEATHER BUREAU. "Wind Data by Direction and Force (Beaufort) for Marsden Squares 448-461, 480-571, 585-587; Areas 24, 26, 27, 28." Tabulated CONFIDENTIAL CONFIDENTIAL by the U.S. Weather Bureau from Weather Bureau Decks: 115 (U.S. Merchant Marine Deck, 1941- 1948) ; 116 (U.S. Merchant Marine Deck, 1949-1953) ; 192 (Hamburg, Deutsche Seewarte Deck) ; 193 (Nederlands, Meteorologisch Instituut Deck) ; 194 (Great Britain, Meteorological Office Deck) ; 195 (U.S. Navy Ships' Logs Observations Deck) ; 281 (U.S. Navy MAR Synoptic Deck) ; and from deck logs of Operation HIGHJUMP, Operation WIND- MILL, Voyage of the ATKA, Japanese Whalers, Norwegian Whalers, Unidentified Whalers via the Union of South Africa, and the French Antarctic Expedition (1948-1951) . Unpublished. 172. VALLAUX, CAMILLE. "La circulation de surface et de Profondeur dans l'Ocean Austral (Surface and deep circulation in the Southern Ocean) ," Revu?. Generale des Science,s Pures et Appliquees, tome 49, no. 12, p. 313-321, 1938. 173. VESTINE, E. H., AND SNYDER, ' E. J. "The Geographic Incidence of Auroral Magnetic Disturbance, South- ern Hemisphere," Terrestrial Magnetism and At- mospheric Electricity, vol. 50, no. 2, p. 105-124. Baltimore: Johns Hopkins Press. 1945. 174. VILLAIN, C. M. "Cartes des lignes cotidales dans les oceans (Charts of the cotidal lines for the oceans) ," Annales Hydrographiques, ser. 4, tome 3, no. 4, p. 269-388, 1952. 175. WADE, ARTHUR. "The Geology of the Antarctic Conti- nent and Its Relationship to Neighbouring Land Areas," Proceedings of the Royal Society 0/Queens- land, vol. 52, pt. 1, p. 24-35, 1941. 176. WADE, F. A. "Petrologic and Structural Relations of the Edsel Ford Range, Marie Byrd Land, to Other Antarctic Mountains," Bulletin of the Geological Society of America, vol. 48, p. 1387-1396, 1937. 177. WATERS, A. W. "Bryozoa," Resultats du Voyage du S. Y. BELGICA en 1897-1898-1899, Zoologie, 1904. 114 p. 178. WILTON, D. W. "Observation of Temperature and Density of Sea Water Made on Board the S. Y. SCOTIA, 1902-1904," Transactions of The Royal Society of Edinburgh, vol. 51, pt. 1, no. 4, p. 78-169, 1915. 1!79. WILTON, D. W., PIRIE, J. H. H., AND BROWN, R. N. R. "Zoological Log; Scottish Antarctic Expedition," Report of the Scientific Results of the Voyage of S. Y. SCOTIA During the Years 1902, 1903, and 1904, vol. 4, pt. 1, p. 1-101, 1908. 180. WORDIE, J. M. "The Ross Sea Drift of the AURORA in 1915-1916," Geographical Journal, vol. 58, p. 219- 224. 1921. 181. . "Shackleton Antarctic Expedition, 1914- 1917; Depths and Deposits of the Weddell Sea," Transactions of the Royal Society of Edinburgh, vol. 52, no. 4, p. 781-793, 1921. 182. . "Shackleton Antarctic Expedition, 1914- 1917; Geological Observations in the Weddell Sea Area," Transactions of the Royal Society of Edin- burgh, vol. 53, no. 2, p. 17-27, 1925. 183. WRIGHT, C. B., AND PRIESTLEY, R. E. "Glaciology," British Antarctic (Terra Nova) Expedition, 1910- 1913. London: Harrison and Sons, Ltd. 1922. 581 p. 184. WUST, G. "Das Ozeanographische Beobachtungs- material (Serienmessungen) " (Oceanographic Ob- servational Material (Serial Measurements) ), Wissenschaftliche Ergebnisse der deutschen at- lantischen Expedition auf dem Forschungs- und Vermessungsschiff METEOR, 1925=1927, bd. 4, tl. 2. p. 17-280, 1932. PAGE 2250X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 CONFIDENTIAL NIS 69 CHARTS 185. ARGENTINA, ? MINISTERIO DE MARINA, DIRECCION GENERAL DE NAVEGACION E HIDROGRAFIA. Navigation Charts: 31; 64, 65, 100, 101, 103, 104, 114, 116. 186. AUSTRALIA, ROYAL 'AUSTRALIAN NAVY, HYDROGRAPHIC BRANCH. Navigation Chart: 08. 187. GERMANY, OBERKOMMANDO DER KRIEGSMARINE. Naviga- ?.tion .Charts: 384, 397, 402, 547, 1057, 1062; 2702, 2704. 188. GREAT- BRITAIN, HYDROGRAPHIC DEPARTMENT. Naviga- NAVY-JANUARY 1956 189. U.S. HYDROGRAPHIC OFFICE. Contoured Position Plot- ing Sheets (BC series) : 0110S-0115S, 0209S-0217S, 0309S-03175, 0408S-0417S, 0507S-0517S, 0608S-0617S, 0709S-0717S, 0810S-0817S, 0910S-0917S, 1010S-1018S, 1110S-1118S, 1209S-12185, 1308S-1318S, 14075-1418S, 1508S-15155, 1609S-16155, 17095-1715S, 1810S-1815S, 19105-1915S, 20095-2015S, 2109S-21155, 22085-2215S, 2307S-2315S, 2408S-24155, 2509S-2514S, 26105-2614S, 27105-2714S, 28105-2814S, 29105-2914S, 3009S-3014S, 3108S-3114S, 3207S-3214S, 3308S-3314S, 3409S-3414S, 3509S-35145, 3610S-3614S. tion Charts: 1774, 2202A, 2202B, 2203, 2683, 3170, 190. Navigation Charts: 0453, 0454, 0825, 958, 2003, . 2451, 2452, 2453, 3570, 3866, 3875, 5411, 5412, 3171, 3172; 3173,3174, 3175, 3176, 3177, 3196, 3202, 5446, 3205, 3213,- 3570, 3571, 3579, 3585, 3589, 3593, 3596, 5801, 6636, 6637, 6638, 6639, 6640, 6641, 6650, 6652, 3866. 6653, 6654, 6661, 16321-24, 16429. PAGE 22-94 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? ? r /14110 A. COASTAL SECTOR 1. DECEPTION ISLAND. Argentine base at head of small bay in southeast part of island. Approximate position 62?59'S., 60?34'W. Probably 1954. Nwv, -PI EDmONT GLACIER ierwitior I. ? Jr> 4' ? ? t k t " I figt . _ gar: 'CALVING ICE8ERGS.. _- r? ? -.2.1Z. ? ? ? .77.7 ? -4 . . .6 ? ? rr.o- ?-? - - - ? ??????4.1, -,- - PVV- .11???? ???? - - ? - - - - _ ? - r 4?4ro. ^ k. ? ? ; r ? . ? .440: ? 1. 1:1:4166 rfkil .2,14 ? - !. IISEBREAKER - ???? /5.? - ? ... , - ? -????-? B. COASTAL SECTOR 1. MARGUERITE BAY. Note sea ice in foreground, cliff ed front of glacier in background, and steep, rocky terrain in right background. Photo portrays type of coast common to many areas of Antarctica. Arrow de- notes direction of ice movement. Approximate position 68?S., 62?W. 1948. CONFIDENTIAL 50X1 FIGURE Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release 2 50-Yr 2013/12/18: CIA-RDp97-00952R000200250001-2 A. COASTAL SECTOR 2. NORTHERN EXTREMITY OF PETER I ISLAND. Approximate position 68?43'S., 90?32'W. February 1955. B. COASTAL SECTOR 3. KAINAN BAY IN EAST EDGE OF Ross ICE SHELF. Landing place (27) . View eastward from west of bay showing U.S.S. Glacier of "Operation DEEPFREEZE" breaking out ice for berthing of cargo ships. Shelf ice in foreground and background, bay ice in middleground. Approximate position 78?S., 162?W. 1956. FIGURE 22-50 CONFIDENTIAL Declassified in Part- Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ,5 Declassified in Part- Sanitized Copy Approved for Release @50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 _ A. COASTAL SECTOR 3. KAINAN BAY IN EAST EDGE OF Ross ICE SHELF. Landing place (27). Supply ship and icebreaker of "Operation DEEPFREEZE" moored to bay ice at head of bay. Approximate po- sition 78?S., 162?W. 1956. ? , ? . ? I-vs!! *;. '17 ; ? ? is. :A:CM r, , , t, ? ?Ii,i^ii_.=LI; ? ? ? B. COASTAL SECTOR 3. KAINAN BAY IN EAST EDGE OF ROSS ICE SHELF. Landing place (27). Photograph taken during "Operation DEEPFREEZE." View looking south over bay ice in foreground, shelf ice in left middle- ground, and pressure area in right background. Approximate position 78?S., 162?W. 1956. CONFIDENTIAL FIGURE 22-51 50X1 Declassified in Part - Sanitized Copy Approved for Release ? 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release n 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 AT J. LJ avaax? A. COASTAL SECTOR 3. BAY OF WHALES, IN EAST EDGE OF ROSS ICE SHELF. Landing place (28). View northeastward with pressure-ridged bay ice in foreground. A 1955 expedition reported that the Bay of Whales was destroyed by extensive calving of the Ross Ice Shelf. Approximate position 78?S., 164?W. 1947. ,Y1,54.r. 101. B. COASTAL SECTOR 3. BAY OF WHALES, IN EAST EDGE OF ROSS ICE SHELF. Landing place (28) . Supply ships at edge of bay ice in left middleground, close pack in center middleground, shelf ice in foreground and background. A 1955 expedition reported that the Bay of Whales was destroyed by extensive calving of the Ross Ice Shelf. Approximate position 78?S., 164?W. 1947. FIGURE 22-52 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? ? A. COASTAL SECTOR 3. WEST OF BAY OF WHALES. Pack ice, made up of fragments of sea ice, in foreground, and the edge of the Ross Ice Shelf in background. Approximate position 78?S., 178?W. 1955. B. COASTAL SECTOR 3. Ross ISLAND AT CAPE EVANS. Landing place (32) . Open water of McMurdo Sound in background. Hut Camp established by Captain R. E. Scott in 1911 in middleground. Approximate position 78?S., 167?E. 1956. CONFIDENTIAL FIGURE 22-550X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved for Release e 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 -1 A. COASTAL SECTOR 3. McMuRDo SOUND. View southeastward showing supply ships of "Operation DEEP- FREEZE" moored to ice at head of McMurdo Sound. Inaccessible Island in left background and Tent Island in right background. Approximate position 78?S., 166?E. 1956. B. COASTAL SECTOR 3. FRANKLIN ISLAND. View westward from U.S.S. Glacier of "Operation DEEP- FREEZE" lying approximately 12 n. miles east of the island. Approximate position 76?S., 168?E. 1956. C. COASTAL SECTOR 4. COASTAL AREA NEAR CAPE FOLGER. Oblique view of ice-free islands in background and con- tinental ice in right foreground, separated by moraine composed of rock fragments. Arrow denotes direction of ice movement. Approximate position 66?S., 111?E. 1947-48. FIGURE 22-54 CONFIDENTIAL Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 ? ? 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2913/12/18: CIA-RDP97-00952R000200250001-2 A. COASTAL SECTOR 4. ICE-FREE COASTAL AREA AT LANDING PLACE (54). In contrast to Vestfold Hills in FIGURE 22-55B, note blanket of rock fragments covering surface of hills. Approximate position 66?S., 101?E. 1947-48. >. %Hr.. '7.414: ? r kr t, - , , " - ? 1/ ? - r????- tror,A9.- - ? ? zApt. Tt " 4 ???? . _ .. _ ? Z;:t"'"1.14: - `.?-7'11v.*:-..-- '4? ' ? . *, -- ' e-7411&41t.".;, 44%." 1...--?+.- -7- - --:- ?-"--- -7.--1 = t . irtc..? "t*--- - ADELIE PENGUIN ROOKERY 12 FT.) Ns? (.45?,2's)bes1?I9v ,s-F"CIL0 40 60 80 ICON (SALILMMA, o RREYC OCANLSE) 30? 20? 10? 10? E 20? 30? 40? 130?E 120?E 110?E 100? E 90 EAST 80?E 70?E 60?E 50?E STATE OF SEA, SUMMER (JANUARY, FEBRUARY, MARCH) . IIIISOUTIBS show percent frequency of seas 55 feet. CONFIDENTIAL STATE OF SEA, SUMMER FIGURE 22-oz 50X1 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 Declassified in Part - Sanitized Copy Approved forRelease @50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 140? 150? 160? 170? 180? 170? 160? 150? TAS 140? 130?W 120?W NIS 69 110?W 100?W 0? WEST 80?W 70?W 60?W - RELIABILITY DIAGRAM E-EXCELLENT F-FAIR G-GOOD P-POOR 10 VERY ROUGH (8-12 FT.) 20 HIGH (>12 FT.) CONFIDENTIAL LEGEND-SEA 203?OBSERVATIONS % CALM % CONFUSED SLIGHT (12 FT.) NO DATA RELIABILITY DIAGRAM E-EXCELLENT F-FAIR 0-GOOD P-POOR 04' SUMMARY SCALE (ALL DIRECTIONS) ? ATI \111111111111 1111111111111111 11111111111111111 70? 130?E 120?E 110?E 100?E 90? EAST 80?E 70?E 60?E 50?E AUTUMN 30? 20? 10? 10? 20? 30? 40? SWELL, AuTumN (APRIL, MAY, JUNE) . Isolines show percent frequency of swell >12 feet. rilIVVTTIVATTT A T Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 SWELL, AUTUMN FIGUI. ,67 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NI 69 li CONFIDENTIAL 140? 150? 160? 170? 180? 170? 160? 150? TAS 140? 130?W 120?W 110?W 1000W 90? WEST 80?W Sj 166 O. SOUTH/ AMERICA /0?W 60?W LEGEND-SWELL 203?oBSERVATIONS % NO SWELL % CONFUSED LOW (1-6 FEET) MODERATE (6-12 FT.) HIGH (>)2 FT.)' 20 30 40 +0 vb (P t RELIABILITY DIAGRAM E-EXCELLENT F-FAIR G-GOOD P-POOR 0 20 4000 00 100N) SUMMARY SCALE (ALL DIRECTIONS) 10 ? ef '14 130?E 120? E 110?E 100?E oiti-fLY NO4, 7- 60? H \ORD I` DATA 90? EAST 80?E 70?E 60?E 50?E WINTER 30? 20? 10? 10? 20? 30? 40? SWELL, WINTER (JULY, AUGUST, SEPTEMBER) . Iiolines show percent frequency of swell >12 feet. flrAwrrTnrwy'rT AT Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 50X1 no SWELL, WINTER FIGU-.? __?vu Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NIS 69 CONFIDENTIAL 140? 150? 160? 170? 180? 170? 160? 150? TAS 140? 130?W 120?W 110?W 100? W 50? WEST 80?W 70?W 60?W SOUTH AMERICA LEGEND-SWELL 203.?OBSERVATIONS NO DATA RELIABILITY DIAGRAM E-EXCELLENT F-FAIR G-GOOD P-POOR 60?. % NO SWELL % CONFUSED LOW (1-6 FEET) MODERATE (6-12 FT.) HIGH (>12 FT.) 20 40 SO 0 20 40 40 00 SUMMARY Sail (ALL DIRECTIONS) 1111111111111111 11111111111111 30? 20? Tr..) 10? 10? 20? 30? 60? ???0\??? 911 130?E 120?E 110?E 100?E ,90? EAST 40? 80?E 70?E 60?E 50?E SPRING SWELL, SPRING (OCTOBER, NOVEMBER, DECEMBER) .. Isolines show percent frequency of swell >12 feet. Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-009512R000200250001-2 50X1 ? SWELL, SPRING FIGUitz 44-00 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 9 CONFIDENTIAL LEGEND MUD OR OOZE MUD, SAND rgal MUD, SAND, GRAVEL MUD, SAND, GRAVEL, ROCK 130?W 120?W 110?W 100?W 90? WEST 80?W ]0?W AMERICA 60?W 50?W 40? MMUD, SAND, GRAVEL, ROCK, SHELL MUD, SAND, ROCK MUD, GRAVEL SAND SAND, GRAVEL SAND, GRAVEL, ROCK SAND, SHELL GRAVEL ROCK UNSAMPLED AREAS CONFIDENTIAL 30? 20? 170? 10? 180? _t>/711" ROSS ICE SHELF /. / (7.5"- te/(/ J1? ilI / 170? 10? 160? 20? 150? 30? TASMANIA 140? 40? CONFIDENTIAL 130?E 120?E 110?E 100?E 90? EAST 80?E 10?E 60?E 50?E Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 BOTTOM SEDIMENTS FIGURE 22-73 Declassified in Part - Sanitized Copy Approved for Release @ 50-Yr 2013/12/18: CIA-RDP97-00952R000200250001-2 NAVY-JANUARY 1956 KEY TO PLACES INDICATED ON FIGURE 22-75 NUMERICAL LIST ALPHA I3ETIC A L LIST 1. Riiser-Larsen Peninsula 2. MacKenzie Bay 3. Davis Sea 4. Shackleton Ice Shelf 5. Adelie Coast 6. Commonwealth Bay 7. Cape Adare 8. Scott Island 9. Cape Jones 10 Coulman Island 11. McMurdo Sound 12. Cape Bird 13. Beaufort Island 14. Ross Island 15. Discovery Inlet 16. Bay of Whales 17. Little America 18. Kainan Bay 19. Okuma Bay 20. Cape Colbeck 21. Sulzberger Bay 22. Cape Dart 23. Amundsen Sea 24. Peter I Island 25. Bellingshausen Sea 26. George VI Sound 27. Marguerite Bay 28. Paradise Harbor 29. Port Foster 30. Clothier Harbor 31. Robert Island 32. Yankee Harbor 33. Isla de los Estados 34. Tierra del Fuego 35. Shag Rocks 36. Clerke Rocks 37. Scotia Bay 37A. Scotia Sea 38. Washington Strait 39. Lewthwaite Strait 40. Spine Islet 41. Larsen Islands 42. Coronation Island 43. Snow Hill Island 44. Lockyer Island 45. Princess Martha Coast 46. Norse] Bay* 47. Atka Bay* 48. Admiral Richard E. Byrd Bay* Adare, Cape (7) Adelie Coast (5) Admiral Richard E. Byrd Bay Amundsen Sea (23) Atka Bay (47) Bay of Whales (16) Beaufort Island (13) Bellingshausen Sea (25) Bird, Cape (12) Clerke Rocks (36) Clothier Harbor (30) Colbeck, Cape (20) Commonwealth Bay (6) Coronation Island (42) Coulman Island (10) Dart, Cape (22) Davis Sea (3) Discovery Inlet (15) George VI Sound (26) Isla de los Estados (33) Jones, Cape (9) Kainan Bay (18) Larsen Islands (41) Lewthwaite Strait (39) Little America (17) Lockyer Island (44) Mackenzie Bay (2) Marguerite Bay (27) McMurdo Sound (11) Norsel Bay (46) Okuma Bay (19) Paradise Harbor (28) Peter I Island (24) Port Foster (29) Princess Martha Coast (45) Riiser-Larsen Peninsula (1) Robert Island (31) Ross Island (14) Scotia Bay (37) Scotia Sea (37A) Scott Island (8) Shackleton Ice Shelf (4) Shag Rocks (35) Snow Hill Island (43) Spine Islet (40) Sulzberger Bay (21) Tierra del Fuego (34) Washington Strait (38) Yankee Harbor (32) (48) * Location and name not verified by the U.S. Board on Geographic Names. NIS 69 CONFIDENTIAL W 150? w 160? wr 180? 170? E 160? E E TASMANIA 140? E 130?W 120?W 110?W 100?W 90? WEST 80?W 70?W 60?W 500W 40? w 30? w .2: . 10? E 20? E 30? E 40? E 50? `Z` et\ 600 ,, C.) \ \ A i'' X 8 \ w V 23 22 , =.-r='-' .,,,..),, \ , ..z, -"'.- % t ? ,...,-..-.1 ?????-? ,,r 03 18 _ 17--2--.0?9 o ROSS ) 70? 15 , ',fit ROSS ICE SHEIF i .;:- )11 80? f Ni7/,? ii),),( 60 ? 0 . OR _ S UTH ? 30 - 28 27 26c-: ,-,-4- ': '''''';'---- y ' ?... A ? . i ,.__. _., ... 0 . G k? \- ''' _ i. Is ,2 800 TIC A ,..-_ I ' 0 SOUTH A , AMERICA . , Nr" . ,,? 34 ili 3 'A KLAND ISL NDS , KE PA -SAGE . SH. LA ? ISLA DS / ,a5 3 1 . 4 3' 9 , ' 29 ? 40 37A 38 / \\souTH ORGIA ,36 . . SOUTI sHASNADN a, CH 50' 24 I 70? 4 SOUTH OR EY .. . . ? s r Do o4 , 46 . . 45 j70? i 48 60? ' ARC , ' , 25 --...... 80? CAMPB --L---1 LAND ; UCKLAND ISLANDS MACQUARIE I.SLAND. k n BALLENY , . ISLANDS /. . ,...., ,,c ki 1 10, 14 felitin ,p, 0 ? \uf, Q,k' qt' 0 V ? - - * C ?ZET ?-_ ? - ISL ND . -. . ,? ? .:? ,, , ,, . . RG EN ISL Nps.- BOUVET. (.) ISLAND k ' . PRINCE EDWARD HSLANDS? ISLANDS',-- : ? 14 i--_,Jr,if ?-1 ,