The sub-Antarctic zone[1] is a region in the Southern Hemisphere, located immediately north of the Antarctic region. This translates roughly to a latitude of between 46° and 60° south of the Equator. The subantarctic region includes many islands in the southern parts of the Atlantic, Indian, and Pacific oceans, especially those situated north of the Antarctic Convergence. Sub-Antarctic glaciers are, by definition, located on islands within the sub-Antarctic region. All glaciers located on the continent of Antarctica are by definition considered to be Antarctic glaciers.

The Antarctic region and its boundary, the Antarctic Convergence


The sub-Antarctic region comprises two geographic zones and three distinct fronts. The northernmost boundary of the subantarctic region is the rather ill-defined Subtropical Front (STF), also referred to as the Subtropical Convergence. To the south of the STF is a geographic zone, the Subantarctic Zone (SAZ). South of the SAZ is the Subantarctic Front (SAF). South of the SAF is another marine zone, called the Polar Frontal Zone (PFZ). The SAZ and the PFZ together form the subantarctic region. The southernmost boundary of the PFZ (and hence, the southern border of the subantarctic region) is the Antarctic Convergence, located approximately 200 kilometers south of the Antarctic Polar Front (APF).[2]

Influence of the Antarctic Circumpolar Current and thermohaline circulation

Diagram of the major ocean currents, showing the Antarctic Circumpolar Current (ACC). In addition to the global thermohaline circulation, the ACC strongly influences regional and global climate.
Global thermohaline circulation strongly influences regional and global climate. Blue paths represent deep-water currents, while red paths represent surface currents.

The sub-Antarctic Front, found between 48°S and 58°S in the Indian and Pacific Ocean and between 42°S and 48°S in the Atlantic Ocean, defines the northern boundary of the Antarctic Circumpolar Current (or ACC).[2] The ACC is the most important ocean current in the Southern Ocean, and the only current that flows completely around the Earth. Flowing eastward through the southern portions of the Atlantic, Indian, and Pacific Oceans, the ACC links these three otherwise separate oceanic basins. Extending from the sea surface to depths of 2000–4000 meters, and with a width of as great as 2000 kilometers, the ACC transports more water than any other ocean current.[3] The ACC carries up to 150 Sverdrups (150 million cubic meters per second), equivalent to 150 times the volume of water flowing in all the world's rivers.[4] The ACC and the global thermohaline circulation strongly influence regional and global climate as well as underwater biodiversity.[5]

Another factor that contributes to the climate of the subantarctic region, though to a much lesser extent than the thermohaline circulation, is the formation of Antarctic Bottom Water (ABW) by halothermal dynamics. The halothermal circulation is that portion of the global ocean circulation that is driven by global density gradients created by surface heat and evaporation.

Definition of subantarctic: political versus scientific

Diagram showing different water masses in the Southern Ocean.

Several distinct water masses converge in the immediate vicinity of the APF or Antarctic Convergence (in particular the Subantarctic Surface Water (Subantarctic Mode Water or SAMW), Antarctic Surface Water, and the Antarctic Intermediate Water). This convergence creates a unique environment, noted for its very high marine productivity, especially for antarctic krill. Because of this, all lands and waters situated south of the Antarctic Convergence are considered to belong to the Antarctic from a climatological, biological and hydrological standpoint. However, the text of the Antarctic Treaty, article VI ("Area covered by Treaty") states: "The provisions of the present Treaty shall apply to the area south of 60° South latitude".[6] Therefore, Antarctica is defined from a political standpoint as all land and ice shelves south of 60°S latitude.

Subantarctic islands

Antarctica and surrounding islands in relation to the Antarctic Convergence and the 60th parallel south
Trees growing along the north shore of the Beagle Channel, 55°S.

The Tristan da Cunha Group, Gough Island, Amsterdam Island, and Saint Paul Island are all isolated volcanic islands situated at between 37°–40° south of the Equator, just south of the southern horse latitudes. Because they are located far to the north of the Antarctic Convergence and have a relatively temperate climate, they are not typically considered to be subantarctic islands.

At between about 46°–50° south of the Equator, in the region often referred to as the Roaring Forties, are the Crozet Islands, Prince Edward Islands, Bounty Islands, Snares Islands, Kerguelen Islands, Antipodes Islands, and Auckland Islands. The geography of these islands is characterized by tundra, with some trees on Snares and Auckland Islands. These islands are all located near the Antarctic Convergence (with Kerguelen south of the Convergence) and are properly considered to be subantarctic islands.

At between 51°–56° south of the Equator, the Falkland Islands, Isla de los Estados, Ildefonso Islands, Diego Ramírez Islands, and other islands associated with Tierra del Fuego and Cape Horn, lie north of the Antarctic Convergence in the region often referred to as the Furious Fifties. Unlike other subantarctic islands, these islands have trees, temperate grasslands (mostly tussac grass), and even arable land. They also lack tundra and permanent snow and ice at their lowest elevations. Despite their more southerly location, it is debatable whether these islands should be considered as such because their climate and geography differs significantly from other subantarctic islands.

At between 52°–57° south of the Equator, the Campbell Island Group, Heard Island and McDonald Islands, Bouvet Island, the South Georgia Group, Macquarie Island, and the South Sandwich Islands are also located in the Furious Fifties. The geography of these islands is characterized by tundra, permafrost, and volcanoes. These islands are situated close to or south of the Antarctic Convergence, but north of 60° S latitude (the continental limit according to the Antarctic Treaty).[6] Therefore, although some are located south of the Antarctic Convergence, they should still be considered as subantarctic islands by virtue of their location north of 60° S.

At between 60°–69° south of the Equator, the South Orkney Islands, South Shetland Islands, Balleny Islands, Scott Island, and Peter I Island are all properly considered to be Antarctic islands for the following three reasons:

  1. they are all located south of the Antarctic Convergence
  2. they are all located within the Southern (or Antarctic) Ocean
  3. they are all located south of the 60th parallel south (in the region often referred to as the Shrieking Sixties)

In light of the above considerations, the following should be considered to be subantarctic islands:

Name of island group Coordinates[7][8] Ocean[7] Administered by
Antipodes Islands 49°40′S 178°46′E Pacific Ocean New Zealand
Auckland Islands 50°42′S 166°05′E Pacific Ocean New Zealand
Bounty Islands 47°45′S 179°03′E Pacific Ocean New Zealand
Bouvet Island (Bouvetøya) 54°26′S 03°24′E Atlantic Ocean Norway
Campbell Island Group 52°32′S 169°08′E Pacific Ocean New Zealand
Crozet Islands (French: Îles Crozet or officially Archipel Crozet) 46°25′S 51°59′E Indian Ocean France
Heard Island and McDonald Islands (HIMI) 53°04′S 73°00′E Indian Ocean Australia
Kerguelen Islands 49°15′S 69°35′E Indian Ocean France
Macquarie Island 54°38′S 158°52′E Pacific Ocean Australia
Prince Edward Islands 46°46′S 37°51′E Indian Ocean South Africa
South Georgia Group 54°30′S 37°00′W Atlantic Ocean United Kingdom
South Sandwich Islands 57°30′S 27°00′W Atlantic Ocean United Kingdom
Snares Islands 48°01′S 166°32′E Pacific Ocean New Zealand

Subantarctic glaciers

This is a list of glaciers in the subantarctic. This list includes one snow field (Murray Snowfield). Snow fields are not glaciers in the strict sense of the word, but they are commonly found at the accumulation zone or head of a glacier.[9] For the purposes of this list, Antarctica is defined as any latitude further south than 60° (the continental limit according to the Antarctic Treaty).[6]

Satellite image of the southern tip of Heard Island. Cape Arkona is seen on the left side of the image, with Lied Glacier just above and Gotley Glacier just below. Big Ben Volcano and Mawson Peak are seen at the lower right side of the image.
Satellite image of central South Georgia: Harker Glacier, Cumberland Bay, Thatcher Peninsula, Allardyce Range, Mount Paget.
Neumayer Glacier, Cumberland West Bay, South Georgia, circa 1882–1883.
Neumayer Glacier, Cumberland West Bay, South Georgia, circa 1882–1883.
Nordenskjold Glacier, Cumberland Bay, South Georgia.
Name of Glacier Coordinates[7][8] Length or (Width)[7] Location
Abbotsmith Glacier 53°6′S 73°24′E 4.8 km Heard Island
Allison Glacier 53°04′S 73°24′E Heard Island
Austin Glacier 54°4′S 37°12′W South Georgia Group
Bary Glacier 54°26′S 36°47′W South Georgia Group
Baudissin Glacier 53°2′S 73°26′E (2.8 km) Heard Island
Bertrab Glacier 54°37′S 35°57′W "small" South Georgia Group
Bogen Glacier 54°48′S 35°56′W "small" South Georgia Group
Briggs Glacier 54°1′S 37°8′W South Georgia Group
Brøgger Glacier 54°32′S 36°26′W 13 km South Georgia Group
Brown Glacier 53°4′S 73°39′E Heard Island
Brunonia Glacier 54°3′S 37°29′W South Georgia Group
Buxton Glacier 54°26′S 36°12′W South Georgia Group
Challenger Glacier 53°2′S 73°28′E Heard Island
Christensen Glacier 54°2′S 36°52′W South Georgia Group
Christensen Glacier 54°28′S 3°24′E Bouvet Island
Christophersen Glacier 54°25′S 36°47′W South Georgia Group
Clayton Glacier 54°4′S 37°26′W South Georgia Group
Compton Glacier 53°3′S 73°37′E Heard Island
Cook Glacier 54°27′S 36°11′W South Georgia Group
Crean Glacier 54°8′S 37°1′W 6 km South Georgia Group
Deacock Glacier 53°11′S 73°31′E Heard Island
Dead End Glacier 54°47′S 35°56′W South Georgia Group
Downes Glacier 53°2′S 73°31′E Heard Island
Ealey Glacier 53°2′S 73°35′E Heard Island
Eclipse Glacier 54°23′S 36°5′W South Georgia Group
Esmark Glacier 54°13′S 37°13′W South Georgia Group
Fiftyone Glacier 53°11′S 73°34′E Heard Island
Fortuna Glacier 54°6′S 36°51′W South Georgia Group
Geikie Glacier 54°17′S 36°41′W South Georgia Group
Gotley Glacier 53°10′S 73°27′E 13.2 km Heard Island
Graae Glacier 54°48′S 36°1′W 3.2 km South Georgia Group
Grace Glacier 54°4′S 37°23′W South Georgia Group
Hamberg Glacier 54°21′S 36°31′W South Georgia Group
Harker Glacier 54°22′S 36°32′W South Georgia Group
Harmer Glacier 54°46′S 36°15′W South Georgia Group
Heaney Glacier 54°25′S 36°12′W South Georgia Group
Helland Glacier 54°29′S 36°37′W South Georgia Group
Henningsen Glacier 54°27′S 36°42′W South Georgia Group
Herz Glacier 54°41′S 35°58′W South Georgia Group
Hindle Glacier 54°34′S 36°5′W 10 km South Georgia Group
Hodges Glacier 54°16′S 36°32′W South Georgia Group
Horntvedt Glacier 54°25′S 3°21′E Bouvet Island
Jacka Glacier 53°00′S 73°20′E 1.3 km Heard Island
Jenkins Glacier 54°46′S 36°7′W South Georgia Group
Jewell Glacier 54°16′S 37°8′W South Georgia Group
Keilhau Glacier 54°16′S 37°4′W 8 km South Georgia Group
Kjerulf Glacier 54°21′S 36°51′W South Georgia Group
König Glacier 54°1′S 36°48′W South Georgia Group
Lancing Glacier 54°2′S 36°56′W South Georgia Group
Lewald Glacier 54°45′S 35°52′W South Georgia Group
Lied Glacier 53°9′S 73°26′E Heard Island
Lucas Glacier 54°4′S 37°18′W South Georgia Group
Lyell Glacier 54°17′S 36°37′W South Georgia Group
Mary Powell Glacier Heard Island
Morris Glacier 54°5′S 37°14′W South Georgia Group
Murray Snowfield 54°9′S 37°9′W South Georgia Group
Nachtigal Glacier 54°29′S 36°9′W South Georgia Group
Neumayer Glacier 54°15′S 36°41′W 13 km South Georgia Group
Nordenskjöld Glacier 54°22′S 36°22′W "large" South Georgia Group
Novosilski Glacier 54°4′S 36°18′W 13 km South Georgia Group
Paget Glacier 54°24′S 36°28′W 6 km South Georgia Group
Peters Glacier 54°8′S 37°33′W South Georgia Group
Philippi Glacier 54°49′S 36°3′W South Georgia Group
Posadowsky Glacier 54°25′S 32°2′E Bouvet Island
Price Glacier 54°7′S 37°29′W South Georgia Group
Purvis Glacier 54°6′S 37°1′W South Georgia Group
Quensel Glacier 54°46′S 35°5′W "small" South Georgia Group
Risting Glacier 54°46′S 36°6′W South Georgia Group
Ross Glacier 54°33′S 36°6′W 10 km South Georgia Group
Ryan Glacier 54°3′S 37°36′W South Georgia Group
Salomon Glacier 54°47′S 35°54′W South Georgia Group
Schmidt Glacier 53°3′S 73°24′E Heard Island
Schrader Glacier 54°7′S 37°39′W South Georgia Group
Spenceley Glacier 54°35′S 36°19′W South Georgia Group
Stephenson Glacier 53°6′S 73°42′E Heard Island
Storey Glacier 54°47′S 36°1′W South Georgia Group
Twitcher Glacier 54°43′S 35°56′W 6 km South Georgia Group
Tyrrell Glacier 54°22′S 36°31′W South Georgia Group
Vahsel Glacier 53°4′S 73°23′E Heard Island
Webb Glacier 54°32′S 36°1′W 3.2 km South Georgia Group
Weddell Glacier 54°35′S 36°00′W 3.2 km South Georgia Group
Wheeler Glacier 54°36′S 36°22′W 3.2 km South Georgia Group
Winston Glacier 53°9′S 73°38′E Heard Island


Impact of climate change on SAMW

Air-sea exchange of CO2

Together, the Subantarctic Mode Water (SAMW) and Antarctic Intermediate Water (AAIW) act as a carbon sink, absorbing atmospheric carbon dioxide and storing it in solution. If the SAMW temperature increases as a result of climate change, the SAMW will have less capacity to store dissolved carbon dioxide. Research using a computerized climate system model suggests that if atmospheric carbon dioxide concentration were to increase to 860 ppm by the year 2100 (roughly double today's concentration), the SAMW will decrease in density and salinity. The resulting reductions in the subduction and transport capacity of SAMW and AAIW water masses could potentially decrease the absorption and storage of CO2 in the Southern Ocean.[10]

Flora and fauna

  • Main: Category: Flora of subantarctic islands, and Category: Fauna of subantarctic islands.

The Antarctic realm and Antarctic Floristic Kingdom include most of the subantarctic islands native biota, with many endemic genera and species of flora and fauna.

Subantarctic island example

The physical landscape and biota communities of Heard Island and McDonald Islands are constantly changing due to volcanism, strong winds and waves, and climate change. Volcanic activity has been observed in this area since the mid-1980s, with fresh lava flows on the southwest flanks of Heard Island. Satellite imagery shows that McDonald Island increased in size from about 1 to 2.5 square kilometers between 1994 and 2004, as a result of volcanic activity.[11]

In addition to new land being produced by volcanism, global warming of the climate is causing the retreat of glaciers on the islands (see section below ). These combined processes produce new ice-free terrestrial and freshwater ecoregions, such as moraines and lagoons, which are now available for colonization by plants and animals.[11]

Heard Island has vast colonies of penguins and petrels, and large harems of land-based marine predators such as elephant seals and fur seals. Due to the very high numbers of seabirds and marine mammals on Heard Island, the area is considered a "biological hot spot".[11] The marine environment surrounding the islands features diverse and distinctive benthic habitats that support a range of species including corals, sponges, barnacles and echinoderms. This marine environment also serves as a nursery area for a range of fishes, including some species of commercial interest.[11]

Retreat of subantarctic glaciers

Retreat of San Rafael Glacier from 1990 to 2000. San Quintín Glacier is shown in the background

Glaciers are currently retreating at significant rates throughout the southern hemisphere. With respect to glaciers of the Andes mountains in South America, abundant evidence has been collected from ongoing research at Nevado del Ruiz in Colombia,[12][13] Quelccaya Ice Cap and Qori Kalis Glacier in Peru,[14][15] Zongo, Chacaltaya and Charquini glaciers in Bolivia,[16] the Aconcagua River Basin in the central Chilean Andes,[17] and the Northern Patagonian and Southern Patagonian ice fields.[18][19][20] Retreat of glaciers in New Zealand[21] and Antarctica is also well documented.

Many subantarctic glaciers are also in retreat. Mass balance is significantly negative on many glaciers on Kergeulen Island, Heard Island, South Georgia and Bouvet Island.[22][23]

Glaciers of Heard Island

Heard Island is a heavily glacierized, subantarctic volcanic island located in the Southern Ocean, roughly 4000 kilometers southwest of Australia. 80% of the island is covered in ice, with glaciers descending from 2400 meters to sea level.[22] Due to the steep topography of Heard Island, most of its glaciers are relatively thin (averaging only about 55 meters in depth).[23] The presence of glaciers on Heard Island provides an excellent opportunity to measure the rate of glacial retreat as an indicator of climate change.[11]

Available records show no apparent change in glacier mass balance between 1874 and 1929. Between 1949 and 1954, marked changes were observed to have occurred in the ice formations above 5,000 feet (1,500 m) on the southwestern slopes of Big Ben, possibly as a result of volcanic activity. By 1963, major recession was obvious below 2,000 feet (610 m) on almost all glaciers, and minor recession was evident as high as 5,000 feet (1,500 m).[24]

Retreat of glacier fronts across Heard Island is evident when comparing aerial photographs taken in December 1947 with those taken on a return visit in early 1980.[22][25] Retreat of Heard Island glaciers is most dramatic on the eastern section of the island, where the termini of former tidewater glaciers are now located inland.[22] Glaciers on the northern and western coasts have narrowed significantly, while the area of glaciers and ice caps on Laurens Peninsula have shrunk by 30% - 65%.[22][23]

During the time period between 1947 and 1988, the total area of Heard Island's glaciers decreased by 11%, from 288 km2 (roughly 79% of the total area of Heard Island) to only 257 km2.[23] A visit to the island in the spring of 2000 found that the Stephenson, Brown and Baudissin glaciers, among others, had retreated even further.[23][25] The terminus of Brown Glacier has retreated approximately 1.1 kilometres since 1950.[11] The total ice-covered area of Brown Glacier is estimated to have decreased by roughly 29% between 1947 and 2004.[25] This degree of loss of glacier mass is consistent with the measured increase in temperature of +0.9 °C over that time span.[25]

The coastal ice cliffs of Brown Glacier and Stephenson Glacier, which in 1954 were over 50 feet (15 m) high, had disappeared by 1963 when the glaciers terminated as much as 100 yards (91 m) inland.[24] Baudissin Glacier on the north coast has lost at least 100 vertical feet (30 vertical m), and Vahsel Glacier on the west coast has lost at least 200 vertical feet (61 vertical m).[24] Winston Glacier, which retreated approximately one mile (1.6 km) between 1947 and 1963, appears to be a very sensitive indicator of glacier change on the island. The young moraines flanking Winston Lagoon show that Winston Glacier has lost at least 300 vertical feet (91 vertical m) of ice within a recent time period.[24]

The glaciers of Laurens Peninsula, whose maximum elevation is only 500 m above sea level, are smaller and shorter than most of the other Heard Island glaciers, and therefore much more sensitive to temperature effects. Accordingly, their total area has decreased by over 30 percent. Jacka Glacier on the east coast of Laurens Peninsula has also demonstrated marked recession since 1955.[24] In the early 1950s, Jacka Glacier had receded only slightly from its position in the late 1920s, but by 1997 it had receded about 700 m back from the coastline.[22][23][26][27]

Possible causes of glacier recession on Heard Island include:

  1. Volcanic activity
  2. Southward movement of the Antarctic Convergence: such a movement conceivably might cause glacier retreat through a rise in sea and air temperatures
  3. Climatic change

The Australian Antarctic Division conducted an expedition to Heard Island during the austral summer of 2003–04. A small team of scientists spent two months on the island, conducting studies on avian and terrestrial biology and glaciology. Glaciologists conducted further research on the Brown Glacier, in an effort to determine whether glacial retreat is rapid or punctuated. Using a portable echo sounder, the team took measurements of the volume of the glacier. Monitoring of climatic conditions continued, with an emphasis on the impact of Foehn winds on glacier mass balance.[28] Based on the findings of that expedition, the rate of loss of glacier ice on Heard Island appears to be accelerating. Between 2000 and 2003, repeat GPS surface surveys revealed that the rate of loss of ice in both the ablation zone and the accumulation zone of Brown Glacier was more than double average rate measured from 1947 to 2003. The increase in the rate of ice loss suggests that the glaciers of Heard Island are reacting to ongoing climate change, rather than approaching dynamic equilibrium.[25] The retreat of Heard Island's glaciers is expected to continue for the foreseeable future.[22]

See also


  1. Editorial guidelines – sub-Arctic
  2. Ryan Smith; Melicie Desflots; Sean White; Arthur J. Mariano; Edward H. Ryan (2008). "Surface Currents in the Southern Ocean:The Antarctic CP Current". The Cooperative Institute for Marine and Atmospheric Studies (CIMAS). Archived from the original on 14 June 2010. Retrieved 1 June 2010.
  3. Klinck, J; Nowlin, W. D. Jr. (2001). "Antarctic Circumpolar Current". In Steele, John H. (ed.). Encyclopedia of Ocean Science (1st ed.). New York: Academic Press. pp. 151–159. doi:10.1006/rwos.2001.0370. ISBN 9780122274305.
  4. Joanna Gyory; Arthur J. Mariano; Edward H. Ryan. "The Gulf Stream". The Cooperative Institute for Marine and Atmospheric Studies (CIMAS). Archived from the original on 1 June 2010. Retrieved 1 June 2010.
  5. Ray Lilley (19 May 2008). "Millions of tiny starfish inhabit undersea volcano". Associated Press. Archived from the original on 9 March 2012. Retrieved 1 June 2010.
  6. Office of Polar Programs (OPP) (26 April 2010). "The Antarctic Treaty". The National Science Foundation, Arlington, Virginia. Archived from the original on 17 January 2012. Retrieved 1 June 2010.
  7. "Antarctic Names". Geographic Names Information System. United States Geological Survey. Retrieved 1 June 2010.
  8. "Antarctic Gazetteer". Australian Antarctic Data Centre. Australian Antarctic Division. Archived from the original on 28 May 2010. Retrieved 1 June 2010.
  9. Dr. Sue Ferguson, United States Department of Agriculture Forest Service. "Types of Glacier". University of Colorado, Boulder, Colorado: National Snow and Ice Data Center. Archived from the original on 17 April 2010. Retrieved 1 June 2010.
  10. Stephanie M. Downes; Nathaniel L. Bindoff; Stephen R. Rintoul (2009). "Impacts of Climate Change on the Subduction of Mode and Intermediate Water Masses in the Southern Ocean". Journal of Climate. 22 (12): 3289–3302. Bibcode:2009JCli...22.3289D. doi:10.1175/2008JCLI2653.1.
  11. "'Big brother' monitors glacial retreat in the sub-Antarctic". Kingston, Tasmania, Australia: Australian Antarctic Division. 8 October 2008. Archived from the original on 7 May 2013. Retrieved 19 June 2013.
  12. Jon J. Major & Christopher G. Newhall (1989). "Snow and ice perturbation during historical volcanic eruptions and the formation of lahars and floods". Bulletin of Volcanology. 52 (1): 1–27. Bibcode:1989BVol...52....1M. doi:10.1007/BF00641384. S2CID 129043590.
  13. Cristian Huggel; Ceballos, Jorge Luis; Pulgarín, Bernardo; Ramírez, Jair; Thouret, Jean-Claude (2007). "Review and reassessment of hazards owing to volcano–glacier interactions in Colombia" (PDF). Annals of Glaciology. 45 (1): 128–136. Bibcode:2007AnGla..45..128H. doi:10.3189/172756407782282408. S2CID 18144817. Archived (PDF) from the original on 27 March 2009. Retrieved 1 June 2010.
  14. Richard S. Williams Jr. & Jane G. Ferrigno (9 February 1999). "Peruvian Cordilleras". United States Geological Survey, United States Department of the Interior. Archived from the original on 4 June 2008. Retrieved 1 June 2010.
  15. L.G. Thompson; E. Mosley-Thompson; et al. (1 June 2010). "Peru - Quelccaya (1974 - 1983)". Byrd Polar Research Center, Ohio State University, Columbus, Ohio. Archived from the original on 23 June 2010. Retrieved 1 June 2010.
  16. Bernard Francou (Institut de Recherche pour le Développement) (17 January 2001). "Small Glaciers Of The Andes May Vanish In 10-15 Years". UniSci, International Science News. Archived from the original on 20 February 2010. Retrieved 1 June 2010.
  17. Francisca Bown; Andres Rivera; Cesar Acuna (2008). "Recent glacier variations at the Aconcagua Basin, central Chilean Andes" (PDF). Annals of Glaciology. 48 (2): 43–48. Bibcode:2008AnGla..48...43B. doi:10.3189/172756408784700572. S2CID 6319942. Archived (PDF) from the original on 7 July 2011. Retrieved 1 June 2010.
  18. Jonathan Amos (27 April 2004). "Patagonian ice in rapid retreat". BBC News. Archived from the original on 30 September 2009. Retrieved 1 June 2010.
  19. Masiokas, Mariano H.; Rivera, Andrés; Espizua, Lydia E.; Villalba, Ricardo; Delgado, Silvia; Aravena, Juan Carlos (15 October 2009). "Glacier fluctuations in extratropical South America during the past 1000 years". Palaeogeography, Palaeoclimatology, Palaeoecology. 281 (3–4): 242–268. Bibcode:2009PPP...281..242M. doi:10.1016/j.palaeo.2009.08.006. hdl:10533/130935.
  20. Japan Aerospace Exploration Agency (3 September 2008). "Huge glaciers retreat on a large scale in Patagonia, South America". Earth Observation Research Center. Archived from the original on 21 July 2011. Retrieved 1 June 2010.
  21. "Glaciers of New Zealand". Satellite Image Atlas of Glaciers of the World. U.S. Geological Survey. Archived from the original on 9 November 2009. Retrieved 1 June 2010.
  22. Ian F. Allison & Peter L. Keage (1986). "Recent changes in the glaciers of Heard Island". Polar Record. 23 (144): 255–272. doi:10.1017/S0032247400007099. S2CID 130086301.
  23. Andrew Ruddell (2010-05-25). "Our subantarctic glaciers: why are they retreating?". Glaciology Program, Antarctic CRC and AAD. Archived from the original on 13 February 2014. Retrieved 19 June 2013.
  24. G.M. Budd; P.J. Stephenson (1970). "Recent glacier retreat on Heard Island" (PDF). International Association for Scientific Hydrology. 86: 449–458. Archived (PDF) from the original on 19 June 2011. Retrieved 7 June 2010.
  25. Douglas E. Thost; Martin Truffer (February 2008). "Glacier Recession on Heard Island, Southern Indian Ocean". Arctic, Antarctic, and Alpine Research. 40 (1): 199–214. doi:10.1657/1523-0430(06-084)[THOST]2.0.CO;2. S2CID 130245283. Archived from the original on 4 December 2012. Retrieved 7 June 2010.
  26. Quilty, P.G. & Wheller, G. (2000). "Heard Island and the McDonald Islands: A window into the Kerguelen Plateau (Heard Island Papers)". Pap. Proc. R. Soc. Tasm. 133 (2): 1–12.
  27. Budd, G.M. (2000). "Changes in Heard Island glaciers, king penguins and fur seals since 1947 (Heard Island Papers)". Pap. Proc. R. Soc. Tasm. 133 (2): 47–60.
  28. "Australian Research Expeditions - Heard Island". Kingston, Tasmania, Australia: Department of the Environment, Water, Heritage and the Arts, Australian Antarctic Division, Territories, Environment and Treaties Section. Archived from the original on 16 February 2011. Retrieved 7 June 2010.

Further reading

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