DOCSLIB.ORG

Pacific Ocean

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Pacific Ocean ARCTIC OCEAN GREENLAND Baffin Bay (Denmark) Laptev Sea Beaufort Sea Kara Sea East Siberian Sea Barents Sea Davis Strait Norwegian Sea Alaska (USA) ICELAND FINLAND R USSIA SWEDEN North NORWAY Hudson Bay Sea ESTONIA Bering Sea LATVIA DENMARK Sea of LITHUANIA Okhotsk UNITED KINGDOM CANA D A IRELAND BELARUS NETHERLANDS POLAND BELGIUM GERMANY CZECH REP UKRAINE LUXEMBOURG SLOVAKIA KAZAKH S T A N AUSTRIA FRANCE LIECHTENSTEIN HUNGARY MOLDOVA SWITZERLAND M ONGOLIA SLOVENIA ROMANIA C ITALY a s p SERBIA i CROATIA Black a MONACO GEORGIA n SAN MARINO S BULGARIA Sea ARMENIA e a ANDORRA VATICAN UZBEKISTAN KYRGYZSTAN UNI T E D STAT E S BOSNIA & HERZ AZERBAIJAN SPAIN NORTH MACEDONIA NORTH KOREA PORTUGAL MONTENEGRO OF AM E RIC A GREECE TURKEY TURKMENISTAN KOSOVO TAJIKISTAN Azores (PRT) ALBANIA M Gibraltar (GBR) SOUTH KOREA JAPAN e MALTA Ceuta (ESP) di CYPRUS SYRIA Melilla (ESP) t e CHINA S rr LEBANON Madeira (PRT) TUNISIA e a IRAQ AFGHANISTAN a ne PALESTINIAN TERRITORIES IRAN an Bermuda (GBR) MOROCCO ISRAEL JORDAN PAKISTAN The Canaries (ESP) KUWAIT ALGERIA T East h NEPAL e LIBYA G China u BHUTAN EGYPT BAHRAIN lf Sea Gulf of Mexico ATLANTIC OCEAN BAHAMAS Western Sahara QATAR M EXICO SAUDI UAE TAIWAN CUBA ARABIA PACIFIC OCEAN Cayman HAITI I NDI A HONG KONG Islands (GBR) PUERTO RICO (USA) R BURMA (MYANMAR) MACAU Hawaiian e OMAN DOMINICAN REP BANGLADESH Islands (USA) MAURITANIA d LAOS BELIZE ANGUILLA (GBR) ERITREA S Arabian Sea MALI e JAMAICA ANTIGUA & BARBUDA NIGER a VIRGIN ISLANDS (USA and GBR) GUAM (USA) HONDURAS ST. KITTS & NEVIS n Guadeloupe (FRA) e THAILAND DOMINICA CAPE VERDE CHAD SUDAN d GUATEMALA SENEGAL YEMEN A Caribbean Martinique (FRA) ST. LUCIA f South f o Sea Netherlands BURKINA ul EL SALVADOR BARBADOS G Bay of Bengal CAMBODIA China PHILIPPINES MARSHALL ISLANDS Antilles (NL) FASO MICRONESIA DJIBOUTI ST. VINCENT & GREN. GAMBIA VIETNAM Sea NICARAGUA GUINEA BISSAU BENIN GRENADA COSTA RICA NIGERIA VENEZUELA TRINIDAD & TOBAGO ETHIOPIA GUINEA KIRIBATI GHANA SRI LANKA PANAMA GUYANA CENTRAL SOUTH SIERRA LEONE AFRICAN REPUBLIC SUDAN PALAU FRENCH GUIANA (FRA) CAMEROON BRUNEI COLOMBIA SURINAME LIBERIA TOGO MALDIVES MALAYSIA COTE D'IVOIRE INDIAN OCEAN NAURU Galapagos EQ GUINEA UGANDA Islands (Ecuador) SOMALIA SAO TOME & PRINCIPE KENYA SINGAPORE GABON ECUADOR DEMOCRATIC REPUBLIC REPUBLIC OF CONGO OF CONGO RWANDA SEYCHELLES INDONESIA PAPUA NEW GUINEA TANZANIA BURUNDI SOLOMON ISLANDS PERU MALAWI BRA ZIL Ascension Island (GBR) TIMOR LESTE TUVALU ANGOLA COMOROS Timor SAMOA Sea American Samoa (USA) ZAMBIA PACIFIC OCEAN FIJI Niue BOLIVIA French Polynesia (FRA) St. Helena (GBR) VANUATU TONGA MOZAMBIQUE ZIMBABWE MADAGASCAR MAURITIUS Reunion Island (FRA) PARAGUAY BOTSWANA New Caledonia (FRA) NAMIBIA ATLANTIC OCEAN A U STRA LIA KEY SWAZILAND SOUTH Location risk level Aon Terrorism & Political Violence Risk Map Portal AFRICA LESOTHO URUGUAY Negligible Risk Tasman C HIL E ARGENTINA Low Risk Sea Medium Risk NEW ZEALAND High Risk Severe Risk 2020 Terrorism & Line of Control Falkland Islands (GBR) To access the portal, please visit https://www.riskmaps.aon.co.uk/TerrorismRisk/Map and register or use your login details. Scotia Sea Political Violence Risk Map SOUTHERN OCEAN About The Risk Advisory Group Risk Advisory provides intelligence, investigations, screening and security management to support Aon’s approach to terrorism and political violence risk management combines threat assessment, organisations dealing with complex international threats. Our guidance, intelligence and analysis help many of impact analysis and crisis management consulting, with individually structured insurance programmes. the world’s foremost businesses negotiate challenging and uncertain environments to choose the right For further information, visit: aon.com/terrorismmap opportunities, in the right markets, with the right partners. For further information, please visit www.riskadvisory.com This map is intended for general use only and should not be used for legal or navigational purposes. The boundaries and names shown do not assert any legal status of any area or the demarcation of any boundary. We do not oer any warranties as to map precision and we cannot be held responsible for any inaccuracies. © Copyright Aon plc 2020. All rights reserved..
Load more

Recommended publications
  • North America Other Continents
    Arctic Ocean Europe North Asia America Atlantic Ocean Pacific Ocean Africa Pacific Ocean South Indian America Ocean Oceania Southern Ocean Antarctica LAND & WATER • The surface of the Earth is covered by approximately 71% water and 29% land. • It contains 7 continents and 5 oceans. Land Water EARTH’S HEMISPHERES • The planet Earth can be divided into four different sections or hemispheres. The Equator is an imaginary horizontal line (latitude) that divides the earth into the Northern and Southern hemispheres, while the Prime Meridian is the imaginary vertical line (longitude) that divides the earth into the Eastern and Western hemispheres. • North America, Earth’s 3rd largest continent, includes 23 countries. It contains Bermuda, Canada, Mexico, the United States of America, all Caribbean and Central America countries, as well as Greenland, which is the world’s largest island. North West East LOCATION South • The continent of North America is located in both the Northern and Western hemispheres. It is surrounded by the Arctic Ocean in the north, by the Atlantic Ocean in the east, and by the Pacific Ocean in the west. • It measures 24,256,000 sq. km and takes up a little more than 16% of the land on Earth. North America 16% Other Continents 84% • North America has an approximate population of almost 529 million people, which is about 8% of the World’s total population. 92% 8% North America Other Continents • The Atlantic Ocean is the second largest of Earth’s Oceans. It covers about 15% of the Earth’s total surface area and approximately 21% of its water surface area.
    [Show full text]
  • Effects of Europe's Commercial Expansion Into the Indian Ocean On
    Effects of Europe’s Commercial Expansion into the Indian Ocean on Asian and African Coastal Economies, 1600-1650 Johannes Lang 8GRG Neulandschule Grinzing Alfred Wegener-Gasse 10-12 1190 Wien 29.1.2016 Betreut von Mag. Ruth Schabauer Abstract This work examines the impact of Europeans’ commercial expansion into the Indian Ocean on the local Asian and African economies between 1600 and 1650. By studying this historically important period of time, we can also gain a deeper understanding of modern globalization and of Europe’s continuing political and economic influence today. The different consequences for the various regions bordering the Indian Ocean are compared, contrasted, and evaluated. For my research I use primarily books and articles but also rely on the analysis of economic data. Epic poems from Mughal writers as well as modern studies are included so that the reader may gain thorough insights into the topic. As I try to tell history from an Afro-Asian perspective, I let both 17th century and contemporary voices native to the Indian Ocean have their say. I conclude in my study that the consequences of trade with the Europeans differed greatly between the heterogeneous regions. The nature of these consequences depended on the socioeconomic structure as well as on the environmental particularities of the regions in question. Some economies profited from the new situation; others suffered from the altered trade system. Interestingly, many effects of 17th century globalization, such as increased competition with countries far away and a heightened reliance on foreign trade, are visible also in today’s process of globalization.
    [Show full text]
  • Recent Declines in Warming and Vegetation Greening Trends Over Pan-Arctic Tundra
    Remote Sens. 2013, 5, 4229-4254; doi:10.3390/rs5094229 OPEN ACCESS Remote Sensing ISSN 2072-4292 www.mdpi.com/journal/remotesensing Article Recent Declines in Warming and Vegetation Greening Trends over Pan-Arctic Tundra Uma S. Bhatt 1,*, Donald A. Walker 2, Martha K. Raynolds 2, Peter A. Bieniek 1,3, Howard E. Epstein 4, Josefino C. Comiso 5, Jorge E. Pinzon 6, Compton J. Tucker 6 and Igor V. Polyakov 3 1 Geophysical Institute, Department of Atmospheric Sciences, College of Natural Science and Mathematics, University of Alaska Fairbanks, 903 Koyukuk Dr., Fairbanks, AK 99775, USA; E-Mail: [email protected] 2 Institute of Arctic Biology, Department of Biology and Wildlife, College of Natural Science and Mathematics, University of Alaska, Fairbanks, P.O. Box 757000, Fairbanks, AK 99775, USA; E-Mails: [email protected] (D.A.W.); [email protected] (M.K.R.) 3 International Arctic Research Center, Department of Atmospheric Sciences, College of Natural Science and Mathematics, 930 Koyukuk Dr., Fairbanks, AK 99775, USA; E-Mail: [email protected] 4 Department of Environmental Sciences, University of Virginia, 291 McCormick Rd., Charlottesville, VA 22904, USA; E-Mail: [email protected] 5 Cryospheric Sciences Branch, NASA Goddard Space Flight Center, Code 614.1, Greenbelt, MD 20771, USA; E-Mail: [email protected] 6 Biospheric Science Branch, NASA Goddard Space Flight Center, Code 614.1, Greenbelt, MD 20771, USA; E-Mails: [email protected] (J.E.P.); [email protected] (C.J.T.) * Author to whom correspondence should be addressed; E-Mail: [email protected]; Tel.: +1-907-474-2662; Fax: +1-907-474-2473.
    [Show full text]
  • Variability in the Location. of the Antarctic Polar Front (90 °
    JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 102, NO. C13, PAGES 27,825-27,833, DECEMBER 15, !997 Variability in the location.of the Antarctic Polar Front (90ø- 20øW) from satellite sea surface temperature data J. Keith Moore, Mark R. Abbott, and James G. Richman Collegeof Oceanicand AtmosphericSciences, Oregon State University, Corvallis Abstract. The path of the AntarcticPolar Front (PF) is mappedusing satellite sea surfacetemperature data from the NOAA/NASA Pathfinderprogram. The mean path and variabilityof the PF are stronglyinfluenced by bathymetry.Meandering intensity is weaker where the bathymetryis steeplysloped and increasesin areaswhere the bottom is relativelyflat. There is an inverserelationship between meandering intensity and both the width of the front and the changein temperatureacross it. There is a persistent,large separationbetween the surfaceand subsurfaceexpressions of the PF at Ewing Bank on the Falkland Plateau. 1. Introduction of meanderingjets and fronts hasbeen done previouslyfor the PF [Legeckis,1977] and other strongfrontal systems[Hansen TheAntarctic Polar Front (PF) is a strongjet within t•e and Maul, 1970; Olsonet al., 1983; Cornilion, 1986]. Antarctic CircumpolarCurrent (ACG), which flowseastward Satellite altimeter data has shown that there is little zonal continuouslyaround Antarctica [Nowlin and Klinck, 1986].The coherencein the variabilityof the ACC [Fu and Chelton,1984; PF, also known as the Antarctic Convergence,is the location Sandwelland Zhang, 1989; Chelton et al., 1990; Gille, 1994; where Antarctic surfacewaters movingto the north sink rap- Gille and Kelly,1996]. These studies emphasize the importance idly belowSubantarctic waters [Deacon, 1933, 1937].Thus the of local and regionalinstabilities [Chelton et al., 1990;Gille and PF is a regionof elevatedcurrent speeds and stronghorizontal Kelly,1996].
    [Show full text]
  • India in the Indian Ocean Donald L
    Naval War College Review Volume 59 Article 6 Number 2 Spring 2006 India in the Indian Ocean Donald L. Berlin Follow this and additional works at: https://digital-commons.usnwc.edu/nwc-review Recommended Citation Berlin, Donald L. (2006) "India in the Indian Ocean," Naval War College Review: Vol. 59 : No. 2 , Article 6. Available at: https://digital-commons.usnwc.edu/nwc-review/vol59/iss2/6 This Article is brought to you for free and open access by the Journals at U.S. Naval War College Digital Commons. It has been accepted for inclusion in Naval War College Review by an authorized editor of U.S. Naval War College Digital Commons. For more information, please contact [email protected]. Color profile: Generic CMYK printer profile Composite Default screen Berlin: India in the Indian Ocean INDIA IN THE INDIAN OCEAN Donald L. Berlin ne of the key milestones in world history has been the rise to prominence Oof new and influential states in world affairs. The recent trajectories of China and India suggest strongly that these states will play a more powerful role in the world in the coming decades.1 One recent analysis, for example, judges that “the likely emergence of China and India ...asnewglobal players—similar to the advent of a united Germany in the 19th century and a powerful United States in the early 20th century—will transform the geopolitical landscape, with impacts potentially as dramatic as those in the two previous centuries.”2 India’s rise, of course, has been heralded before—perhaps prematurely. How- ever, its ascent now seems assured in light of changes in India’s economic and political mind-set, especially the advent of better economic policies and a diplo- macy emphasizing realism.
    [Show full text]
  • Satellite Ice Extent, Sea Surface Temperature, and Atmospheric 2 Methane Trends in the Barents and Kara Seas
    The Cryosphere Discuss., https://doi.org/10.5194/tc-2018-237 Manuscript under review for journal The Cryosphere Discussion started: 22 November 2018 c Author(s) 2018. CC BY 4.0 License. 1 Satellite ice extent, sea surface temperature, and atmospheric 2 methane trends in the Barents and Kara Seas 1 2 3 2 4 3 Ira Leifer , F. Robert Chen , Thomas McClimans , Frank Muller Karger , Leonid Yurganov 1 4 Bubbleology Research International, Inc., Solvang, CA, USA 2 5 University of Southern Florida, USA 3 6 SINTEF Ocean, Trondheim, Norway 4 7 University of Maryland, Baltimore, USA 8 Correspondence to: Ira Leifer ([email protected]) 9 10 Abstract. Over a decade (2003-2015) of satellite data of sea-ice extent, sea surface temperature (SST), and methane 11 (CH4) concentrations in lower troposphere over 10 focus areas within the Barents and Kara Seas (BKS) were 12 analyzed for anomalies and trends relative to the Barents Sea. Large positive CH4 anomalies were discovered around 13 Franz Josef Land (FJL) and offshore west Novaya Zemlya in early fall. Far smaller CH4 enhancement was found 14 around Svalbard, downstream and north of known seabed seepage. SST increased in all focus areas at rates from 15 0.0018 to 0.15 °C yr-1, CH4 growth spanned 3.06 to 3.49 ppb yr-1. 16 The strongest SST increase was observed each year in the southeast Barents Sea in June due to strengthening of 17 the warm Murman Current (MC), and in the south Kara Sea in September. The southeast Barents Sea, the south 18 Kara Sea and coastal areas around FJL exhibited the strongest CH4 growth over the observation period.
    [Show full text]
  • Sea-Level Rise for the Coasts of California, Oregon, and Washington: Past, Present, and Future
    Sea-Level Rise for the Coasts of California, Oregon, and Washington: Past, Present, and Future As more and more states are incorporating projections of sea-level rise into coastal planning efforts, the states of California, Oregon, and Washington asked the National Research Council to project sea-level rise along their coasts for the years 2030, 2050, and 2100, taking into account the many factors that affect sea-level rise on a local scale. The projections show a sharp distinction at Cape Mendocino in northern California. South of that point, sea-level rise is expected to be very close to global projections; north of that point, sea-level rise is projected to be less than global projections because seismic strain is pushing the land upward. ny significant sea-level In compliance with a rise will pose enor- 2008 executive order, mous risks to the California state agencies have A been incorporating projec- valuable infrastructure, devel- opment, and wetlands that line tions of sea-level rise into much of the 1,600 mile shore- their coastal planning. This line of California, Oregon, and study provides the first Washington. For example, in comprehensive regional San Francisco Bay, two inter- projections of the changes in national airports, the ports of sea level expected in San Francisco and Oakland, a California, Oregon, and naval air station, freeways, Washington. housing developments, and sports stadiums have been Global Sea-Level Rise built on fill that raised the land Following a few thousand level only a few feet above the years of relative stability, highest tides. The San Francisco International Airport (center) global sea level has been Sea-level change is linked and surrounding areas will begin to flood with as rising since the late 19th or to changes in the Earth’s little as 40 cm (16 inches) of sea-level rise, a early 20th century, when climate.
    [Show full text]
  • Geography Notes.Pdf
    THE GLOBE What is a globe? a small model of the Earth Parts of a globe: equator - the line on the globe halfway between the North Pole and the South Pole poles - the northern-most and southern-most points on the Earth 1. North Pole 2. South Pole hemispheres - half of the earth, divided by the equator (North & South) and the prime meridian (East and West) 1. Northern Hemisphere 2. Southern Hemisphere 3. Eastern Hemisphere 4. Western Hemisphere continents - the largest land areas on Earth 1. North America 2. South America 3. Europe 4. Asia 5. Africa 6. Australia 7. Antarctica oceans - the largest water areas on Earth 1. Atlantic Ocean 2. Pacific Ocean 3. Indian Ocean 4. Arctic Ocean 5. Antarctic Ocean WORLD MAP ** NOTE: Our textbooks call the “Southern Ocean” the “Antarctic Ocean” ** North America The three major countries of North America are: 1. Canada 2. United States 3. Mexico Where Do We Live? We live in the Western & Northern Hemispheres. We live on the continent of North America. The other 2 large countries on this continent are Canada and Mexico. The name of our country is the United States. There are 50 states in it, but when it first became a country, there were only 13 states. The name of our state is New York. Its capital city is Albany. GEOGRAPHY STUDY GUIDE You will need to know: VOCABULARY: equator globe hemisphere continent ocean compass WORLD MAP - be able to label 7 continents and 5 oceans 3 Large Countries of North America 1. United States 2. Canada 3.
    [Show full text]
  • Circulation in the Southwestern Part of the Kara Sea in September 2007 A
    ISSN 00014370, Oceanology, 2010, Vol. 50, No. 5, pp. 643–656. © Pleiades Publishing, Inc., 2010. Original Russian Text © A.G. Zatsepin, E.G. Morozov, V.T. Paka, A.N. Demidov, A.A. Kondrashov, A.O. Korzh, V.V. Kremenetskiy, S.G. Poyarkov, D.M. Soloviev, 2010, published in Okeanologiya, 2010, Vol. 50, No. 5, pp. 683–697. MARINE PHYSICS Circulation in the Southwestern Part of the Kara Sea in September 2007 A. G. Zatsepina, E. G. Morozova, V. T. Pakab, A. N. Demidova, A. A. Kondrashovb, A. O. Korzhb, V. V. Kremenetskiya, S. G. Poyarkova, and D. M. Solovievc a Shirshov Institute of Oceanology, Russian Academy of Sciences, Moscow, Russia Email: [email protected] b Atlantic Branch of the Shirshov Institute of Oceanology, Russian Academy of Sciences, Moscow, Russia c Marine Hydrophysical Institute, National Academy of Sciences of Ukraine, Sevastopol, Ukraine Received September 16, 2009; in final form, January 2, 2010 Abstract—During cruise 54 of the R/V Akademik Mstislav Keldysh to the southwestern Kara Sea (September 6 to October 7, 2007), a large amount of hydrophysical data with unique spatial resolution was obtained on the basis of measurements using different instruments. The analysis of the data gave us the possibility to study the dynamics and hydrological structure of the southwestern Kara Sea basin. The main elements of the gen eral circulation are the following: the Yamal Current, the Eastern Novaya Zemlya Current, and the St. Anna Trough Current. All these currents are topographically controlled; they flow over the bottom slopes along the isobaths. The Yamal Current begins at the Kara Gates Strait and turns to the east as part of the cyclonic cir culation.
    [Show full text]
  • A Newly Discovered Glacial Trough on the East Siberian Continental Margin
    Clim. Past Discuss., doi:10.5194/cp-2017-56, 2017 Manuscript under review for journal Clim. Past Discussion started: 20 April 2017 c Author(s) 2017. CC-BY 3.0 License. De Long Trough: A newly discovered glacial trough on the East Siberian Continental Margin Matt O’Regan1,2, Jan Backman1,2, Natalia Barrientos1,2, Thomas M. Cronin3, Laura Gemery3, Nina 2,4 5 2,6 7 1,2,8 9,10 5 Kirchner , Larry A. Mayer , Johan Nilsson , Riko Noormets , Christof Pearce , Igor Semilietov , Christian Stranne1,2,5, Martin Jakobsson1,2. 1 Department of Geological Sciences, Stockholm University, Stockholm, 106 91, Sweden 2 Bolin Centre for Climate Research, Stockholm University, Stockholm, Sweden 10 3 US Geological Survey MS926A, Reston, Virginia, 20192, USA 4 Department of Physical Geography (NG), Stockholm University, SE-106 91 Stockholm, Sweden 5 Center for Coastal and Ocean Mapping, University of New Hampshire, New Hampshire 03824, USA 6 Department of Meteorology, Stockholm University, Stockholm, 106 91, Sweden 7 University Centre in Svalbard (UNIS), P O Box 156, N-9171 Longyearbyen, Svalbard 15 8 Department of Geoscience, Aarhus University, Aarhus, 8000, Denmark 9 Pacific Oceanological Institute, Far Eastern Branch of the Russian Academy of Sciences, 690041 Vladivostok, Russia 10 Tomsk National Research Polytechnic University, Tomsk, Russia Correspondence to: Matt O’Regan ([email protected]) 20 Abstract. Ice sheets extending over parts of the East Siberian continental shelf have been proposed during the last glacial period, and during the larger Pleistocene glaciations. The sparse data available over this sector of the Arctic Ocean has left the timing, extent and even existence of these ice sheets largely unresolved.
    [Show full text]
  • Modification and Pathways of Southern Ocean Deep Waters in the Scotia
    Deep-Sea Research I 49 (2002) 681–705 Modification and pathways of Southern Ocean Deep Waters in the Scotia Sea Alberto C. Naveira Garabatoa,*, Karen J. Heywooda, David P. Stevensb a School of Environmental Sciences, University of East Anglia, Norwich NR4 7TJ, UK b School of Mathematics, University of East Anglia, Norwich NR4 7TJ, UK Received 11 September 2000; received in revised form 11 June 2001; accepted 23 October 2001 Abstract An unprecedented high-quality, quasi-synoptic hydrographic data set collected during the ALBATROSS cruise along the rim of the Scotia Sea is examined to describe the pathways of the deep water masses flowing through the region, and to quantify changes in their properties as they cross the sea. Owing to sparse sampling of the northern and southern boundaries of the basin, the modification and pathways of deep water masses in the Scotia Sea had remained poorly documented despite their global significance. Weddell Sea Deep Water (WSDW) of two distinct types is observed spilling over the South Scotia Ridge to the west and east of the western edge of the Orkney Passage. The colder and fresher type in the west, recently ventilated in the northern Antarctic Peninsula, flows westward to Drake Passage along the southern margin of the Scotia Sea while mixing intensely with eastward-flowing Circumpolar Deep Water (CDW) of the antarctic circumpolar current (ACC). Although a small fraction of the other WSDW type also spreads westward to Drake Passage, the greater part escapes the Scotia Sea eastward through the Georgia Passage and flows into the Malvinas Chasm via a deep gap northeast of South Georgia.
    [Show full text]
  • Chapter 4 Tectonic Reconstructions of the Southernmost Andes and the Scotia Sea During the Opening of the Drake Passage
    123 Chapter 4 Tectonic reconstructions of the Southernmost Andes and the Scotia Sea during the opening of the Drake Passage Graeme Eagles Alfred Wegener Institute, Helmholtz Centre for Marine and Polar Research, Bre- merhaven, Germany e-mail: [email protected] Abstract Study of the tectonic development of the Scotia Sea region started with basic lithological and structural studies of outcrop geology in Tierra del Fuego and the Antarctic Peninsula. To 19th and early 20th cen- tury geologists, the results of these studies suggested the presence of a submerged orocline running around the margins of the Scotia Sea. Subse- quent increases in detailed knowledge about the fragmentary outcrop ge- ology from islands distributed around the margins of the Scotia Sea, and later their interpretation in light of the plate tectonic paradigm, led to large modifications in the hypothesis such that by the present day the concept of oroclinal bending in the region persists only in vestigial form. Of the early comparative lithostratigraphic work in the region, only the likenesses be- tween Jurassic—Cretaceous basin floor and fill sequences in South Geor- gia and Tierra del Fuego are regarded as strong enough to be useful in plate kinematic reconstruction by permitting the interpretation of those re- gions’ contiguity in mid-Mesozoic times. Marine and satellite geophysical data sets reveal features of the remaining, submerged, 98% of the Scotia 124 Sea region between the outcrops. These data enable a more detailed and quantitative approach to the region’s plate kinematics. In contrast to long- used interpretations of the outcrop geology, these data do not prescribe the proximity of South Georgia to Tierra del Fuego in any past period.
    [Show full text]