Bridgeman Island, Antarctica, ‘burning mount’ or old eroded volcano?

Polar Record ◽  
2021 ◽  
Vol 57 ◽  
Author(s):  
Karen Louise Williams
Keyword(s):  
Nineteenth Century ◽  
Volcanic Activity ◽  
South Shetland Islands ◽  
Deception Island ◽  
The South ◽  
Shetland Islands ◽  
Short Period ◽  
South Shetlands ◽  
Volcanic Islands

Abstract Deception, Bridgeman and Penguin are the three most recently active volcanic islands in the South Shetland Islands. Since the discovery of the archipelago in 1819, Deception Island has erupted on frequent occasions, most recently in August 1970. A number of nineteenth-century observers reported fumarolic or volcanic activity from Bridgeman Island. No eyewitness accounts of activity from Penguin Island have been found. A chronological list detailing the historic reports from Bridgeman Island was compiled to compare and establish their veracity. This process revealed a consistency of observation from independent observers. An effort has been made to consider if any of these reports of activity may have belonged instead to Penguin Island volcano, 60 km (32 NM) away. A review of the timing of discovery and availability of the first charts of the South Shetlands was also examined to narrow the period when mariners might have mistaken one island for another. Only the three earliest observations of activity from an unnamed volcano, during the short period when no maps were available, may be questioned. A useful chart of the region was published in 1822, and all subsequent observations of activity were from Bridgeman, not Penguin Island.

Nineteenth century sealing sites on Rugged Island, South Shetland Islands

Polar Record ◽  
2006 ◽  
Vol 42 (4) ◽  
pp. 335-347 ◽  
Author(s):  
Michael Pearson ◽  
Ruben Stehberg
Keyword(s):  
Nineteenth Century ◽  
Early Years ◽  
South Shetland Islands ◽  
The South ◽  
History Museum ◽  
Shetland Islands ◽  
Fur Seals ◽  
Fur Seal ◽  
The Usa ◽  
South Shetlands

The South Shetland Islands were discovered in 1819. Almost immediately the fur seal population was intensively exploited and this lasted through the early years of the 1820s, by which time seal numbers had been so depleted that sealing became uneconomic. Sealing was revived for both fur seals and Elephant seals at several periods later in the century. Sealers were put ashore in gangs and built makeshift shelters in which to live. Many of these have been identified on the South Shetlands, and a number have been excavated, though few with archaeological method. Fifty known sites are identified. The paper outlines the survey and excavation of two sites on Rugged Island by archaeologists from Australia and from the Chilean National Natural History Museum. One site relates to the sealing era of the 1820s, while the second may be associated with a marooned sealing gang in the 1870s. The nature of the occupation sites on the South Shetlands is analysed in relation to the social and operational context of the merchant navies of Britain and the USA in the nineteenth century. This is seen as a more directly relevant context for assessing physical evidence than is the application of theories of global capitalist systems.

Fire Precautions at Antarctic Stations

Polar Record ◽  
1953 ◽  
Vol 6 (46) ◽  
pp. 743-745
Author(s):  
Bernard Stonehouse
Keyword(s):  
South Shetland Islands ◽  
Falkland Islands ◽  
Deception Island ◽  
The South ◽  
Shetland Islands ◽  
Antarctic Expedition ◽  
Terre Adélie ◽  
Hope Bay

In 1946 the Falkland Islands Dependencies Survey station on Deception Island in the South Shetland Islands was completely destroyed by fire. Stores, valuable equipment and the records of many months' work were lost. In 1948 the station at Hope Bay in Trinity Peninsula was burnt down, with the loss of two lives. In January 1952 the hut of the French Antarctic Expedition at Port-Martin in Terre Adélie was destroyed in the same way. Smaller outbreaks of fire, fortunately detected early and dealt with promptly, have been reported from other stations. Of all the difficulties which can overtake a polar expedition, the loss of its base is perhaps the most disastrous. Nevertheless, the frequency with which such losses seem to occur suggests that there are fundamental errors in the design of the huts, as well as a tendency to underestimate the danger of fire.

The Bellingshausen-Palmer meeting

Polar Record ◽  
2015 ◽  
Vol 51 (6) ◽  
pp. 644-654 ◽  
Author(s):  
Rip Bulkeley
Keyword(s):  
Antarctic Peninsula ◽  
South Shetland Islands ◽  
The South ◽  
Shetland Islands ◽  
Contentious Issue ◽  
Balanced Assessment ◽  
Absolute Certainty ◽  
South Shetlands ◽  
The Antarctic

ABSTRACTThe celebrated meeting between Captain Bellingshausen of the Imperial Russian Navy and the American sealing skipper Nathaniel Brown Palmer, off the South Shetland Islands in February 1821, has often been described by following just one or other of the two men's divergent and in some respects irreconcilable accounts. The most contentious issue is whether or not Palmer told Bellingshausen about the existence of a body of land to the south of the South Shetlands, known today as the Antarctic Peninsula. This note attempts to reach a balanced assessment of the matter by examining evidence from both sides, including several previously unconsidered items. It concludes that, although the truth will never be known with absolute certainty, the basic American account is more plausible, by the narrowest of narrow margins, than the Russian.

scholarly journals The lichenicolous fungi of the South Shetland Islands, Antarctica: species diversity and identification guide

2018 ◽  
Vol 87 (4) ◽  
Author(s):  
Vagn Alstrup ◽  
Maria Olech ◽  
Paulina Wietrzyk-Pełka ◽  
Michał Hubert Węgrzyn
Keyword(s):  
Species Diversity ◽  
Literature Survey ◽  
South Shetland Islands ◽  
The South ◽  
Lichenicolous Fungi ◽  
Shetland Islands ◽  
Identification Guide ◽  
South Shetlands

This paper contributes 96 species to the biota of lichenicolous fungi in the South Shetland Islands archipelago. New to science are the following genera: <em>Antarctosphaeria</em> Alstrup &amp; Olech, gen. nov., <em>Dahawkswia</em> Alstrup &amp; Olech, gen. nov., <em>Lichenohostes</em> Alstrup &amp; Olech, gen. nov., <em>Llanorella</em> Alstrup &amp; Olech, gen. nov., <em>Phaeosporodendron</em> Alstrup &amp; Olech, gen. nov., and <em>Prostratomyces</em> Alstrup &amp; Olech, gen. nov. Additionally, 31 species are described as new to science. These are: <em>Antarctosphaeria bireagens</em> Alstrup &amp; Olech, sp. nov., <em>A. lichenicola</em> Alstrup &amp; Olech, sp. nov., <em>Arthonia dufayelensis</em> Alstrup &amp; Olech, sp. nov., <em>A. livingstonensis</em> Alstrup &amp; Olech, sp. nov., <em>A. massalongiae</em> Alstrup &amp; Olech, sp. nov., <em>A. pertusariicola</em> Alstrup &amp; Olech, sp. nov., <em>A. rakusae</em> Alstrup &amp; Olech, sp. nov., <em>Carbonea austroshetlandica</em> Alstrup &amp; Olech, sp. nov., <em>Cercidospora pertusariicola</em> Alstrup &amp; Olech, sp. nov., <em>Dactylospora antarctica</em> Alstrup &amp; Olech, sp. nov., <em>D. haematommatis</em> Alstrup &amp; Olech, sp. nov., <em>Dahawkswia lichenicola</em> Alstrup &amp; Olech, sp. nov., <em>Dendrophoma acarosporae</em> Alstrup &amp; Olech, sp. nov., <em>Didymellopsis antarctica</em> Alstrup &amp; Olech, sp. nov., <em>Lichenohostes citrinospora</em> Alstrup &amp; Olech, sp. nov., <em>Lichenostigma corymbosae</em> Alstrup &amp; Olech, sp. nov., <em>Llanorella ramalinae</em> Alstrup &amp; Olech, sp. nov., <em>Metasphaeria verrucosa</em> Alstrup &amp; Olech, sp. nov., <em>Micarea lichenicola</em> Alstrup &amp; Olech, sp. nov., <em>Phaeospora antarctica</em> Alstrup &amp; Olech, sp. nov., <em>P. convolutae</em> Alstrup &amp; Olech, sp. nov., <em>Phaeosporodendron badiae</em> Alstrup &amp; Olech, sp. nov., <em>Phoma acarosporae</em> Alstrup &amp; Olech, sp. nov., <em>Prostratomyces leprariae</em> Alstrup &amp; Olech, sp. nov., <em>P. ochrolechiae</em> Alstrup &amp; Olech, sp. nov., <em>P. rhizocarpicolae</em> Alstrup &amp; Olech, sp. nov., <em>Rhagadostoma antarctica</em> Alstrup &amp; Olech, sp. nov., <em>Sphaerellothecium placopsiicola</em> Alstrup &amp; Olech, sp. nov., <em>Stigmidium placopsiicola</em> Alstrup &amp; Olech, sp. nov., <em>Taeniolella frigidae</em> Alstrup &amp; Olech, sp. nov., and <em>Tetramelas caloplacae</em> Alstrup &amp; Olech, sp. nov. Furthermore, a literature survey was undertaken, which resulted in the preparation of an identification guide for the lichenicolous species occurring in the South Shetlands Islands.

scholarly journals V.—On the Innes Wilson Collection of Rocks and Minerals from the South Shetland Islands and Trinity Island

1922 ◽  
Vol 53 (1) ◽  
pp. 81-89 ◽  
Author(s):  
Herbert H. Thomas
Keyword(s):  
South Shetland Islands ◽  
Falkland Islands ◽  
Deception Island ◽  
Kind Permission ◽  
The South ◽  
Shetland Islands ◽  
Colonial Office

Mr J. Innes Wilson of Port Stanley, Falkland Islands, during the whaling-season of 1916–17 paid a visit to the South Shetland Islands and Palmer Archipelago. He collected specimens of rocks and minerals from Deception Island, Roberts Island, Trinity Island, and the coast bordering the Gerlache Channel, which were transmitted to the Colonial Office by the Governor, Sir William Douglas Young. It is with the kind permission of the Undersecretary of State for the Colonies that I am allowed to submit some account of Mr Innes Wilson's interesting and important collection.

scholarly journals DecTephra: A new database of Deception Island’s tephra record (Antarctica

2021 ◽  
Author(s):  
Joaquin Hopfenblatt ◽  
Adelina Geyer ◽  
Meritxell Aulinas ◽  
Antonio Polo Sánchez ◽  
Antonio Álvarez-Valero
Keyword(s):  
Volcanic Hazard ◽  
Active Volcano ◽  
Lacustrine Sediment ◽  
South Shetland Islands ◽  
Deception Island ◽  
The South ◽  
Shetland Islands ◽  
Tephra Layers ◽  
The Antarctic ◽  
Eruption Record

&lt;p&gt;Deception Island is the most active volcano in the South Shetland Islands (Antarctica) with more than 20 eruptions in the in the last two centuries, including the 1967, 1969 and 1970 most recent eruptive events, and three episodes of volcanic unrest since 1990 (1992, 1999 and 2014-2015). Since the discovery of Deception island in 1820, the number of scientific bases, touristic activities, and air and vessel traffic in the region, have considerably increased. Only the Antarctic Peninsula region, together with the South Shetland Islands, hosts 25 research stations and 3 summer field camps, which are located inside or within a 150 km radius distance from this active volcano. Nearby, the Palmer Archipelago and the north-western coast of the Antarctic Peninsula are both important tourist destinations exceeding 30,000 visitors per year with a significant increase in vessel traffic during the tourist season. This escalation in the amount of exposed infrastructure and population to a future eruption of Deception Island clearly urges the need to advancing our knowledge of the island&amp;#8217;s volcanic and magmatic history and developing improved vulnerability analyses and long-term volcanic hazard assessments. However, past attempts to construct a volcanic hazard map of Deception have always been limited by the lack of a complete eruption record. In this sense, volcanic ash layers found in marine and lacustrine sediment cores, and glaciers outside Deception Island can provide valuable information to: (i) determine the size and explosiveness of past eruptive events; (ii) assess the extent of their related hazards (e.g. ash fall out); (iii) complete the eruption record of the island; and (iv) estimate the island&amp;#8217;s eruption recurrence over time.&lt;/p&gt;&lt;p&gt;In this work, we provide a detailed, and up-to-date, revision of the current knowledge on Deception Island&amp;#8217;s tephra record. &amp;#160;For this, we have compiled the DecTephra (&lt;strong&gt;Dec&lt;/strong&gt;eption Island &lt;strong&gt;Tephra&lt;/strong&gt; Record) database, which seeks recording the most relevant information of all up today known tephra layers with Deception Island as presumed source vent. DecTephra database includes 335 tephra layers (including cryptotephras) found in marine/lacustrine sediment and ice cores. For each tephra layer, we have compiled information regarding: (i) location (e.g. latitude, longitude, region) and characteristics of the sampling site (e.g. length of the sediment or ice core); and (ii) tephra characteristics (e.g. age, chemistry, granulometry). The analysis of the information included in this new database shows that Deception Island&amp;#8217;s tephras can be observed at numerous proximal (&lt; 150 km) sampling sites distributed all along the South Shetland Islands but also as far as in the Scotia Sea (&gt; 1,000 km) and the South Pole (&gt; 2,900 km). Also, identified isochronous tephra horizons allow defining periods of higher explosive eruptive activity in the island during the Holocene.&lt;/p&gt;&lt;p&gt;This research is part of POLARCSIC and PTIVolcan research initiatives. This research was partially funded by the MINECO projects VOLCLIMA (CGL2015-72629-EXP) and VOLGASDEC (PGC2018-095693-B-I00)(AEI/FEDER, UE). A.P.S is grateful for his JAE_Intro scholarship (JAEINT_20_00670).&lt;/p&gt;

scholarly journals Using Fixed-Wing UAV for Detecting and Mapping the Distribution and Abundance of Penguins on the South Shetlands Islands, Antarctica

Drones ◽  
2019 ◽  
Vol 3 (2) ◽  
pp. 39 ◽  
Author(s):  
Pfeifer ◽  
Barbosa ◽  
Mustafa ◽  
Peter ◽  
Brenning ◽  
...  
Keyword(s):  
Austral Summer ◽  
Time Lapse ◽  
Chinstrap Penguin ◽  
South Shetland Islands ◽  
Total Abundance ◽  
The South ◽  
Shetland Islands ◽  
Remote Areas ◽  
Exact Position ◽  
South Shetlands

Antarctic marine ecosystems undergo enormous changes, presumably due to climate change and fishery. Unmanned aerial vehicles (UAVs) have an unprecedented potential for measuring these changes by mapping indicator species such as penguins even in remote areas. We used a battery-powered fixed-wing UAV to survey colonies along a 30-km stretch of the remote coast of southwest King George Island and northwest Nelson Island (South Shetland Islands, Antarctica) during the austral summer 2016/17. With multiple flights, we covered a total distance of 317 km. We determined the exact position of 14 chinstrap penguin colonies, including two small unknown colonies, with a total abundance of 35,604 adults. To model the number of occupied nests based on the number of adults counted in the UAV imagery we used data derived from terrestrial time-lapse imagery. The comparison with previous studies revealed a decline in the total abundance of occupied nests. However, we also found four chinstrap penguin colonies that have grown since the 1980s against the general trend on the South Shetland Islands. The results proved the suitability of the use of small and lightweight fixed-wing UAVs with electric engines for mapping penguin colonies in remote areas in the Antarctic.

scholarly journals Epiphytic diatom community structure and richness is determined by macroalgal host and location in the South Shetland Islands (Antarctica)

PLoS ONE ◽  
2021 ◽  
Vol 16 (4) ◽  
pp. e0250629
Author(s):  
Andrea M. Burfeid-Castellanos ◽  
Rafael P. Martín-Martín ◽  
Michael Kloster ◽  
Carlos Angulo-Preckler ◽  
Conxita Avila ◽  
...  
Keyword(s):  
Climate Change ◽  
Species Richness ◽  
Primary Production ◽  
Image Annotation ◽  
South Shetland Islands ◽  
Ecological Niches ◽  
Deception Island ◽  
The South ◽  
Shetland Islands ◽  
Livingston Island

The marine waters around the South Shetland Islands are paramount in the primary production of this Antarctic ecosystem. With the increasing effects of climate change and the annual retreat of the ice shelf, the importance of macroalgae and their diatom epiphytes in primary production also increases. The relationships and interactions between these organisms have scarcely been studied in Antarctica, and even less in the volcanic ecosystem of Deception Island, which can be seen as a natural proxy of climate change in Antarctica because of its vulcanism, and the open marine system of Livingston Island. In this study we investigated the composition of the diatom communities in the context of their macroalgal hosts and different environmental factors. We used a non-acidic method for diatom digestion, followed by slidescanning and diatom identification by manual annotation through a web-browser-based image annotation platform. Epiphytic diatom species richness was higher on Deception Island as a whole, whereas individual macroalgal specimens harboured richer diatom assemblages on Livingston Island. We hypothesize this a possible result of a higher diversity of ecological niches in the unique volcanic environment of Deception Island. Overall, our study revealed higher species richness and diversity than previous studies of macroalgae-inhabiting diatoms in Antarctica, which could however be the result of the different preparation methodologies used in the different studies, rather than an indication of a higher species richness on Deception Island and Livingston Island than other Antarctic localities.

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