Hubbry Logo
Cape RoydsCape RoydsMain
Open search
Cape Royds
Community hub
Cape Royds
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Cape Royds
Cape Royds
Cape Royds
View on Wikipedia
from Wikipedia

Cape Royds (77°33′S 166°09′E / 77.550°S 166.150°E / -77.550; 166.150 (Cape Royds)) is a dark rock cape forming the western extremity of Ross Island, facing on McMurdo Sound, Antarctica. It was discovered by the British National Antarctic Expedition (BrNAE) (1901–1904) and named for Lieutenant Charles Royds, Royal Navy, who acted as meteorologist on the expedition. Royds subsequently rose to become an Admiral and was later Commissioner of the Metropolitan Police, London. The cape is the site of Shackleton's Hut, the expedition camp of the British Antarctic Expedition, 1907–09.[1]

Key Information

Shackleton's Hut

[edit]
A group of explorers from Shackleton's Nimrod Expedition, 1907–1909, in the Antarctic hut at Cape Royds

Shackleton's Hut (77.552929°S 166.168286°E) is a historical site near Cape Royds, Ross Island, Antarctica, where the explorer Ernest Shackleton built a hut that housed his party during the winter of 1908. When Shackleton went into McMurdo Sound in 1908, having failed to land on King Edward VII Land, he decided to build a hut at Cape Royds, a small promontory twenty-three miles north of Hut Point where Scott had stayed during the Discovery Expedition. The whole shore party lived in this hut through the winter of 1908.[2]

The Antarctic Heritage Trust (New Zealand) has custody over the site. Nominated by AHT, Shackleton's Hut was listed in the 2004, 2006, and 2008 World Monuments Watch by the World Monuments Fund to attract attention and financial support for the site.[3]

Antarctic Specially Protected Area

[edit]

An area of 6200 ha at the cape is protected as Antarctic Specially Protected Area (ASPA 121, incorporating HSM 15) because it supports the southernmost established Adélie penguin colony known, with a long period of population data. The presence of polynyas in McMurdo Sound provides an ice-free area where penguins can feed, and is important for the survival of the penguin colony.[4] The area plays host to penguin researchers such as Jean Pennycook.[5] The area is also important for its terrestrial and freshwater ecology; it is the type locality for several species of algae, including the southernmost record of snow algae.[6]

Lakes

[edit]
Map all coordinates using OpenStreetMap Download coordinates as KML
Cape Royds in west

There are a number of small lakes near the cape.

Blue Lake

[edit]

77°32′S 166°10′E / 77.533°S 166.167°E / -77.533; 166.167. The largest of several small frozen lakes near Cape Royds, lying 0.5 nautical miles (0.93 km; 0.58 mi) north-northeast of Flagstaff Point. Named by the British Antarctic Expedition, 1907–09 on account of the intensely vivid blue color of its ice.[7]

Clear Lake

[edit]

77°32′S 166°09′E / 77.533°S 166.150°E / -77.533; 166.150. A small lake just west-northwest of Blue Lake at Cape Royds. A descriptive name given by the British Antarctic Expedition (1907-09). It is the deepest lake in this vicinity.[8]

Green Lake

[edit]

77°33′S 166°09′E / 77.550°S 166.150°E / -77.550; 166.150. A small lake near the coast, about midway between Pony Lake and Coast Lake at Cape Royds. Named by British Antarctic Expedition, 1907-09, because of its coloring.[9]

Coast Lake

[edit]

77°32′S 166°08′E / 77.533°S 166.133°E / -77.533; 166.133. A small lake at Cape Royds, lying close to the coast, about 0.75 nautical miles (1.39 km; 0.86 mi) north of Flagstaff Point. Named by the British Antarctic Expedition, 1907-09, because of its position.[10]

Pony Lake

[edit]

77°33′S 166°09′E / 77.550°S 166.150°E / -77.550; 166.150. A small lake immediately north of Flagstaff Point at Cape Royds. Named by British Antarctic Expedition, 1907-09, who built their winter hut adjacent to this lake, because they had their ponies tethered nearby.[11]

Deep Lake

[edit]

77°34′S 166°13′E / 77.567°S 166.217°E / -77.567; 166.217. A small elongate lake 0.5 nautical miles (0.93 km; 0.58 mi) north of Cape Barne. The descriptive name was applied by the British Antarctic Expedition, 1907-09.[12]

Sunk Lake

[edit]

77°34′S 166°13′E / 77.567°S 166.217°E / -77.567; 166.217. A small lake lying between Deep Lake and the coast at Cape Royds. The descriptive name appears on the maps by the British Antarctic Expedition, 1910–13, but it may have been given earlier by the British Antarctic Expedition (1907-09). The surface of the ice comprising the lake is 18 ft below sea level.[13]

Terrace Lake

[edit]

77°34′39″S 166°16′54″E / 77.577515°S 166.281582°E / -77.577515; 166.281582. A descriptive name for a small, elongate lake which lies in a valley with moraine from the Barne Glacier, about 0.5 miles (0.80 km) east of Cape Barne. The name appears on the maps of the British Antarctic Expedition (BrAE) (1910-13), but may have been applied earlier by the British Antarctic Expedition (BrAE) (1907-09).[14]

Northern features

[edit]

Features around Cape Royds include Horseshoe Bay, Shackleton's Hut, Blacksand Beach, Flagstaff Point, Backdoor Bay, Mickle Island and Cape Barne.[15]

Features to the north of Cape Royds include, from north to south,

Varcoe Headland

[edit]

77°31′12″S 166°12′42″E / 77.52°S 166.2116667°E / -77.52; 166.2116667. A low headland, 34 metres (112 ft) high, that marks the north entrance point to Horseshoe Bay in west Ross Island. Named by New Zealand Geographic Board (NZGB) after Technical Services Officer Garth Edwin Varcoe, who worked in the NZ Antarctic Program over a period of 15 years until his accidental death in a helicopter crash near this headland in October 1992. His expertise was in the mechanical and electrical areas and he played a leading role in the reconstruction of Scott Base.[16]

Newport Point

[edit]

77°31′34″S 166°11′17″E / 77.5261111°S 166.1880556°E / -77.5261111; 166.1880556. The south entrance point to Horseshoe Bay in west Ross Island. Named by New Zealand Geographic Board (NZGB) after Terry Newport, a carpenter in the NZ Antarctic Program, who perished in a helicopter crash near this point in October 1992.[17]

Horseshoe Bay

[edit]

77°32′S 166°12′E / 77.533°S 166.200°E / -77.533; 166.200. A cove just north of Cape Royds. Discovered and named by the British National Antarctic Expedition (1901-04) under Robert Falcon Scott. The name suggests the shape of the cove.[18]

Blacksand Beach

[edit]

77°33′S 166°08′E / 77.550°S 166.133°E / -77.550; 166.133. A beach formed of black volcanic sand, about 0.5 nautical miles (0.93 km; 0.58 mi) northward of Flagstaff Point. The descriptive name was given by members of the British Antarctic Expedition, 1907-09, who found the beach within safe walking distance of their base hut near Flagstaff Point.[19]

Turret Cone

[edit]

77°33′03″S 166°26′26″E / 77.55096°S 166.440671°E / -77.55096; 166.440671. A small summit about 455 metres (1,493 ft) high, that is locally conspicuous, located 3.8 nautical miles (7.0 km; 4.4 mi) east of Cape Royds and 3 nautical miles (5.6 km; 3.5 mi) northeast of Cape Barne on Ross Island. Descriptively named by Griffith Taylor of the British Antarctic Expedition (British Antarctic Expedition), 1910-13.[20]

Southern features

[edit]

Features to the south of Cape Royds include, from north to south,

Flagstaff Point

[edit]

77°33′S 166°11′E / 77.550°S 166.183°E / -77.550; 166.183. A point forming the south end of the Cape Royds headland. Charted and named by the British Antarctic Expedition under Shackleton, 1907-09, which established its winter headquarters and erected a flag near the point.[21]

Backdoor Bay

[edit]
Main article: Backdoor Bay

77°34′S 166°12′E / 77.567°S 166.200°E / -77.567; 166.200. A small bay lying at the east side of Cape Royds. The British Antarctic Expedition, 1907-09, under Shackleton, unloaded supplies at Backdoor Bay for use at their winter headquarters on Cape Royds. So named by them because it lies at the back (east) side of Cape Royds, opposite the small cove on the west side of the cape, known to them as "Front Door Bay."[22]

Mickle Island

[edit]

77°34′S 166°13′E / 77.567°S 166.217°E / -77.567; 166.217. A very small island 1 nautical mile (1.9 km; 1.2 mi) southeast of Flagstaff Point. Charted and so named by the British Antarctic Expedition led by Shackleton, 1907-09. The name appears to be capricious or whimsical, mickle meaning "great."[23]

Mount Cis

[edit]

77°34′05″S 166°17′24″E / 77.568014°S 166.289902°E / -77.568014; 166.289902. A hill, 184 metres (604 ft) high, located 1.1 nautical miles (2.0 km; 1.3 mi) northeast of Cape Barne in west Ross Island. Named by the British Antarctic Expedition (British Antarctic Expedition), 1907-09, at the suggestion of geologist Raymond Priestley, after one of the expeditionary dogs.[24]

Cape Barne

[edit]

77°35′S 166°14′E / 77.583°S 166.233°E / -77.583; 166.233. A steep, rocky bluff rising to 120 metres (390 ft) high between Cape Royds and Cape Evans. Discovered by the British National Antarctic Expedition, 1901-04, under Scott, and named by him for Lieutenant Michael Barne, Royal Navy, a member of the expedition.[25]

References

[edit]

Sources

[edit]

Public Domain This article incorporates public domain material from websites or documents of the United States Geological Survey.

Revisions and contributorsEdit on WikipediaRead on Wikipedia

Cape Royds

View on Grokipedia
from Grokipedia
Cape Royds is a low-lying, ice-free volcanic cape forming the western extremity of in Antarctica's , located at approximately 77°33'S, 166°10'E and situated about 24 km west of the active volcano (3,795 m). Named after Lieutenant Charles Rawson Royds of the British National Antarctic Expedition (1901–04), it features phonolitic rock formations, several small saline lakes including the prominent Blue Lake, and a beach, making it one of the principal sites of early human activity in the region. As an (ASPA No. 157), access requires a permit to preserve its fragile ecosystem, which includes the southernmost green and crustose lichens in the region. The cape is renowned for its historical significance as the base camp of Sir Ernest Shackleton's British Antarctic (Nimrod) Expedition (1907–09), where the prefabricated hut—now designated Historic Site and Monument (HSM) No. 15—was erected in February 1908 after pack ice prevented access to other sites on . From this robust refuge, Shackleton's 15-man party overwintered for 14 months, launching a sledging attempt that reached within 97 nautical miles of the —the farthest south at the time—and achieving the first ascent of . The well-preserved hut, maintained by the Antarctic Heritage Trust, contains artifacts from the expedition, including provisions and equipment, offering a tangible link to the . Ecologically, Cape Royds supports a diverse Antarctic fauna, most notably the southernmost Adélie penguin (Pygoscelis adeliae) colony in the world, with around 2,000 breeding pairs nesting in ASPA No. 121, which is closed to recreational visits to minimize disturbance. The nearby polynya in McMurdo Sound provides essential open water for foraging, sustaining not only the penguins but also breeding South Polar skuas (Stercorarius maccormicki), haul-out Weddell seals (Leptonychotes weddellii), and occasional sightings of emperor penguins (Aptenodytes forsteri) and leopard seals (Hydrurga leptonyx). Long-term monitoring has documented population fluctuations in the Adélie colony, influenced by sea ice conditions and human impacts, underscoring the site's value for scientific research on climate effects in polar environments.

Geography

Location and Topography

Cape Royds is situated at the western extremity of in , , with central coordinates of approximately 77°33′S 166°10′E. This position places it about 35–37 km north-northwest of , on the edge of the region. The of Cape Royds consists of a narrow, ice-free strip of phonolitic volcanic land, extending approximately 8 km along the coast. The terrain features irregular lava flows, volcanic gravels, and reddish deposits, forming low cliffs (10–20 m high) along the seaward edge, as well as headlands such as Derrick Point and Flagstaff Point, sheltered bays including Backdoor Bay and Horseshoe Bay, pebble beaches, and small valleys. A prominent landscape element is the view of , the active volcano rising 24 km to the east on . The cape lies adjacent to the McMurdo Ice Shelf to the south and opens onto the , with the broader extending beyond. Elevations range from at the coastal beaches to modest hills, such as Turret Cone, reaching up to around 100 m, creating a gently undulating profile amid the surrounding ice-covered terrain. Access to Cape Royds is primarily by marine routes, with small boats or ships anchoring in Backdoor Bay or Horseshoe Bay for landings on the beaches. Overland travel from occurs across the seasonal or via to designated pads near the coast.

Climate and Environment

Cape Royds features a harsh typical of coastal , with extreme temperature fluctuations driven by its proximity to the and influences from the interior. The mean annual air temperature is approximately -20°C, based on long-term observations from nearby stations. During the austral summer (December to February), average temperatures hover around -2°C, with occasional highs reaching 7.5°C, while winter (June to August) sees averages of -25°C to -30°C and lows dipping to -36.8°C. These conditions are moderated somewhat by the polynyas, which expose warmer ocean waters and prevent complete closure, raising local air temperatures during periods of open water. Precipitation is exceedingly low, totaling about 200 mm of water equivalent per year, almost entirely as or , which underscores the region's arid nature despite its coastal location. Winds are a dominant feature, blowing predominantly from the southeast at average speeds of 10 knots (5 m/s), though gusts can exceed 100 knots (51 m/s) during storms; these are augmented by katabatic flows originating from the and deflected by , enhancing sea ice dynamics in . The area experiences continuous daylight from mid-November to late January and total darkness from mid-May to early August, amplifying the seasonal extremes in solar radiation and temperature. Environmental conditions at Cape Royds are shaped by pervasive , which underlies most soils and limits active layer thawing to a few weeks in summer, resulting in cryoturbated and poorly drained terrain. Certain lakes exhibit hypersaline characteristics due to intense evaporation and minimal freshwater input; for instance, Pony Lake reaches salinities exceeding seawater levels during freeze-thaw cycles, fostering unique chemical gradients. The polynyas are critical in this context, sustaining open water year-round through wind-driven ice divergence, which supports nutrient and biological productivity essential for nearby wildlife, including brief access to foraging grounds for Adélie penguins. In recent years, sea ice variability has intensified, with the 2023 winter maximum extent marking a record low of 16.96 million square kilometers (as of September 2023), followed by the second-lowest in 2024 at 17.16 million square kilometers (as of September 2024). These reductions in winter ice extent around , attributed to warmer ocean temperatures and anomalous wind patterns, have disrupted local heat balances and heightened vulnerability to further changes.

Geology

Rock Composition and Formation

Cape Royds is primarily composed of phonolitic rocks, specifically kenyte, an alkaline volcanic rock characterized by large anorthoclase phenocrysts in a fine-grained groundmass. These phonolites form part of the Ross Island volcanic province within the broader McMurdo Volcanic Group, which encompasses extrusive volcanism ranging from Miocene to Holocene epochs. At Cape Royds, the rocks consist of thin flows of phonolitic lavas, partially overlain by volcanic agglomerates and lithic tuffs, resulting from effusive and explosive volcanic activity. K-Ar dating of anorthoclase from these kenyte flows indicates an age of approximately 0.68 ± 0.14 million years, placing their formation in the Middle Pleistocene. The volcanic succession at Cape Royds reflects a progression from older olivine basalt sequences to younger phonolitic units, with the kenyte flows representing a later stage of alkaline in the Volcanic Province. These rocks were extruded during a period of rift-related associated with the West Antarctic Rift System, producing undersaturated lavas that dominate the local . Overlying materials include breccias and minor younger basaltic flows on higher elevations, contributing to the area's heterogeneous volcanic terrain. Soils at Cape Royds are predominantly ornithogenic, formed through the accumulation and modification of penguin from colonies, which enriches the substrate with nutrients such as and , creating fertile patches amid otherwise nutrient-poor ground. These soils develop on the volcanic , exhibiting high organic content and altered in rookery areas. Beaches, such as Blacksand Beach, feature dark sands derived from weathered volcanic debris, including basaltic and phonolitic components that give them a characteristic black hue. The landscape of Cape Royds has been shaped by glacial erosion and periglacial processes, with moraines deposited by retreating glaciers marking former ice extents. Raised beaches, preserved through post-glacial isostatic rebound following the , form prominent and ridges along the , elevated up to several meters above current . These features result from the unloading of ice sheets, which triggered uplift and the stranding of marine sediments.

Volcanic Landmarks

Cape Royds features several distinct volcanic landmarks shaped by the region's alkaline volcanism, primarily associated with the Volcanic Province. The area consists of multiple flows, at least four in number and up to 15 m thick, dated to approximately 0.68 ± 0.14 Ma via K/Ar methods, forming the foundational coastal terrain as extensions of Mount 's lower slopes. These flows contribute to the ice-free phonolitic landscape, with local topography influenced by erosion and subsequent parasitic activity. Mount Cis, a 184 metres (604 ft) high hill located south of Cape Royds and approximately 1 km east of Cape Barne, represents a prominent phonolitic dome partially covered by . It is classified as a high-K cone and serves as a minor parasitic vent on the flank of , characterized by small-volume eruptions that incorporated crustal xenoliths such as sanidinite, , and dolerite. The dome's structure exemplifies the intraplate alkaline magmatism prevalent in the Ross Island , where phonolitic compositions dominate. Other notable features include eroded volcanic remnants like Varcoe Headland and Newport Point, which mark the boundaries of embayments such as Horseshoe Bay and Backdoor Bay; these caldera-like coastal indentations result from differential erosion of flows and pyroclastic deposits. The local is further shaped by ash deposits from the nearby active , a 3,794 m approximately 24 km to the east, whose ongoing eruptions contribute layers that overlay older volcanic units. This proximity underscores Cape Royds's role within the broader system, where radial vents and flows have built the island's framework over the past 1 Ma.

Lakes

Blue Lake

Blue Lake is the largest of several small frozen lakes near Cape Royds on , , situated at 77°32′ S, 166°10′ E and approximately 1 mile from Shackleton's headquarters hut. Named by the British Antarctic Expedition (1907–09) for its intensely vivid blue color, the lake measures about 800 m in length with a maximum recorded depth of 7 m. The lake is perennially ice-covered, with thick ice that has not thawed since early 20th-century observations, creating a stable but extreme aquatic environment. Beneath the ice, Blue Lake supports microbial mats dominated by such as Phormidium murrayi and various diatoms, forming brightly pigmented (red or orange) benthic layers that thrive in the low-light conditions. These mats represent key primary producers in the lake's , contributing to its biogeochemical cycles. Invertebrate life, including rotifers from families like Bdelloidae and Adinetidae, inhabits the lake, particularly at depths up to 15 feet, though no fish species are present due to the harsh conditions. Limnological research on Blue Lake dates back to 1908, when James Murray first sampled its benthic communities by digging through the , with systematic studies intensifying in the 1960s to explore its microbial diversity and stratification. Ongoing investigations, including community analyses, continue to highlight its role as a model for polar freshwater ecosystems.

Clear Lake

Clear Lake is a small freshwater body situated west-northwest of Blue Lake at Cape Royds on , , with an approximate diameter of 0.2 km. It holds the distinction of being the deepest lake in the vicinity, formed within a drowned basin typical of the region's volcanic . The lake remains permanently ice-covered, exhibiting meromictic stratification that maintains distinct layers of water with minimal mixing. Its upper waters are notably clear due to limited nutrient inputs from the surrounding barren landscape, fostering only sparse communities and contributing to high optical transparency. This clarity, for which the lake was descriptively named by the British Expedition (1907–09), has facilitated early investigations into penetration and in freshwater systems, highlighting how minimal allows deeper availability compared to more nutrient-enriched coastal waters. Ongoing limnological monitoring has focused on thermal profiles, revealing persistent temperature gradients where surface layers approach 0°C under the cover, while bottom waters stabilize near 4°C year-round—a consequence of 's density maximum and the insulating lid that prevents seasonal fluctuations in deeper strata. These conditions underscore Clear Lake's role as a model for understanding hydrological stability in isolated polar ecosystems. Lakes at Cape Royds, including Clear Lake, are part of long-term monitoring programs assessing impacts on cover and chemistry.

Green Lake

Green Lake is a small, coastal lake situated midway between Pony Lake and Coast Lake on Cape Royds, the western extremity of in , , at coordinates 77°32'31.9"S, 166°08'57.9"E. It measures approximately 0.15 km in diameter, comprising two lobes—one about 70 m long by 35–40 m wide and a smaller lobe 16 m across—making it one of the five largest lakes in the area. Its coastal exposure places it in a dynamic environment influenced by nearby volcanic terrain and ice-free oases. Hydrologically, Green Lake is shallow, with depths of 1–2 m, and remains perpetually ice-covered, historically with up to 1.75 m of ice overlying the . Fed primarily by in a closed-basin system, it undergoes intense during brief ice-free periods in late summer, resulting in hypersaline conditions; conductivity reaches 4.31 mS/cm, and early measurements revealed underlying with a freezing point of -45°C. The lake's chemistry features dominant Na⁺ and Cl⁻ ions, elevated nutrients from (e.g., total at 166,184 μg/L and NO₃-N at 119 μg/L), and an alkaline pH of 10.24, with broader ranges of 8.7–10.38 supporting biogeochemical processes. The lake's characteristic green coloration stems from prolific algal blooms, including a productive community that imparts a turbid green tint to the , alongside brightly cyanobacterial mats carpeting the benthic sediments. These mats, often orange and 2 cm thick, harbor high concentrations (>2 g/kg) and occasionally lift off the floor, contributing to the lake's unique visual and ecological profile. Unlike neighboring lakes such as Blue Lake, which features blue ice, Green Lake's pigmentation and distinguish it as a hypersaline system ideal for studying microbial adaptations. Since its naming by the British Expedition (1907–1909) for the green hue of its ice, Green Lake has been a key site for biogeochemical , with initial sampling by James Murray in 1908–1909 revealing diversity and . Contemporary studies, including cycling analyses, highlight its nutrient-rich dynamics and stability over a century, providing insights into and climate impacts on closed-basin lakes; pH fluctuations in such systems typically span 7–10, underscoring variable .

Coast Lake

Coast Lake is a small, coastal lake situated at Cape Royds on , , approximately 0.75 nautical miles north of Flagstaff Point and in close proximity to the shoreline near . Mapped during the British Antarctic Expedition (1907–09) under , the lake measures about 0.1 km in diameter and lies within No. 157, which encompasses much of Cape Royds to safeguard its scientific and ecological value. Its position near the sea exposes it to tidal influences, distinguishing it from more inland lakes in the region. The of Coast Lake is characterized by brackish conditions resulting from periodic incursions, with conductivity levels around 8.32 mS/cm indicating moderate suitable for halotolerant organisms. The lake remains ice-covered for most of the year, with summer surface ranging from 4.5 to 6.5, allowing for stratified water columns that may experience mixing from tidal effects. These inputs support a microbial community adapted to saline environments, including such as Phormidium deflexum and rotifers like Adineta grandis, which thrive in the lake's benthic mats and contribute to its productivity. assemblages, including species preserved from early 20th-century samples, further highlight its role as a for salt-tolerant , reflecting ongoing ecological dynamics influenced by coastal proximity. Since the early 2000s, Coast Lake has been monitored as part of broader environmental assessments in the Cape Royds protected area, serving as an indicator site for potential impacts due to its low-lying coastal position and sensitivity to marine incursions. These studies track changes in chemistry, microbial diversity, and shoreline stability to assess long-term effects on freshwater ecosystems. The lake also provides occasional access for Adélie from the nearby colony, though primary foraging occurs in marine environments.

Pony Lake

Pony Lake is a small coastal pond situated north of Flagstaff Point at Cape Royds on , , approximately 120 meters long and 70 meters wide. It lies close to the colony and the , within the region. As a seasonal meltwater lake, Pony Lake freezes solid during winter, forming hypersaline basal brines due to salt exclusion during ice formation, and thaws rapidly in summer from snowmelt, reaching depths of 1-2 meters. This dynamic transition supports a short but intense period of open water, typically from late November to February, during which the lake fills quickly with meltwater inputs. The lake was named during Ernest Shackleton's Nimrod Expedition (1907-1909), after the ponies used by the team that were tethered nearby. Pony Lake has been studied extensively for its nutrient cycling dynamics, particularly the influx of from nearby penguin runoff, which enriches the dissolved pool and drives high biological . Concentrations of ammonium can exceed 5000 µg/L in the , attributed to ornithogenic that fuel microbial and algal processes in this eutrophic system. These studies highlight the lake's role in local biogeochemical cycles, with transformation occurring rapidly during the melt period.

Deep Lake

Deep Lake is a small, elongate lake situated approximately 0.5 nautical miles (0.9 km) north of Cape Barne on , , at coordinates 77°34′S, 166°13′E. The lake measures about 0.45 km in length and 0.1 km in width, forming part of a series of coastal lakes in the region. Its isolation is enhanced by the surrounding volcanic terrain and minimal connectivity to adjacent water bodies, contributing to limited external influences on its . The lake is perennially ice-covered, with ice thickness varying due to differential ablation and underlying gravel layers, including notable features like a 3.3 m high ice cone formed by tilting ice blocks. Hydrologically, it exhibits low , ranging from freshwater to brackish conditions, with seawater intrusion occurring via a subsurface system. The water column shows chemical stratification, with a uniform composition in deeper layers (5.2–8.5 m) indicative of past exceeding inflow during a recent arid period, and the maximum measured depth is 10.6 m via auger sampling. Bottom layers are likely anoxic due to the stable ice cover limiting mixing, though direct measurements confirm meromictic conditions with solar-heated surface waters. Unique features include steep sides carved by glacial action, as the lake occupies a continuation of a glacial groove incised into the volcanic during past ice advances. This glacial morphology results in minimal surface disturbance, with the perennial ice lid and gravel-stabilized margins protecting the lake from wind-driven mixing or significant sediment input, preserving its stratified profile. Deep Lake serves as a key site for paleolimnological research, with studies of surrounding raised marine deposits and evaporite minerals like providing insights into ; for instance, 230Th/234U dating of crystals from the lake edge indicates formation around 4700 years ago, linked to post-glacial marine incursions and evaporation in the Cape Barne area. Sediment analyses from nearby terraces reveal late foraminiferal assemblages, reflecting transitions from marine to lacustrine conditions over the past several thousand years, though direct lake-bottom cores remain limited. These investigations highlight the lake's role in reconstructing regional and climatic variability in the vicinity.

Sunk Lake

Sunk Lake is a small, elongate lakelet situated between Deep Lake and the coast, immediately north of Cape Barne on [Ross Island](/page/Ross Island). Its position places it within the ice-free terrain of Cape Royds, approximately 0.2 km in diameter, contributing to the diverse hydrological features of the area's coastal landscape. The lake's ice surface lies approximately 4.5–6 m below , a depression attributed to resulting from prolonged of glacial ice. This lowering effect highlights the dynamic periglacial processes in the region, where surface melting has led to the gradual sinking of the lake basin over time. Hydrologically, Sunk Lake remains permanently ice-covered year-round, with the ice thickness reflecting minimal summer melt in the harsh environment. Beneath the ice, the lake holds , ranging from freshwater influences to mildly saline conditions influenced by proximity to . The water depth reaches about 12 m in places, supporting limited exchange with surrounding coastal systems. The formation of Sunk Lake is linked to volcanic activity on , where lava flows may have consolidated over preexisting ice, creating enclosed basins susceptible to later . These hypersaline to brackish conditions, combined with the isolated, low-lying setting, make it a notable example of coastal , though detailed modern studies remain limited compared to larger regional lakes.

Terrace Lake

Terrace Lake is a small, elongate lake situated in a moraine valley approximately 0.5 nautical miles (0.9 km) east of Cape Barne on , , at coordinates 77°34′39″S, 166°16′54″E. The lake, with an approximate diameter of 0.3 km, is surrounded by moraines deposited by the Barne Glacier, highlighting its glacial origins as a post-glacial feature formed in a depression carved and filled by ice retreat. The of Terrace Lake is characterized by perennial ice cover and freshwater input influenced by glacial melt, resulting in a body containing glacial that imparts a turbid appearance. Unique terraced benches around the lake represent relic shorelines from fluctuating past lake levels during , providing evidence of the dynamic post-glacial environment in the region. Sediment cores from Terrace Lake have been utilized in research to reconstruct deglaciation timelines, with varved layers offering a high-resolution record of annual glacial retreat and environmental change following the Last Glacial Maximum.

Wildlife and Ecology

Adélie Penguin Colony

The Adélie penguin (Pygoscelis adeliae) colony at Cape Royds represents the southernmost breeding site for this species, situated along the rocky peninsula near Pony Lake and Backdoor Bay on Ross Island in McMurdo Sound. This relatively small rookery has been the subject of continuous monitoring since 1965 as part of one of Antarctica's longest biological time series, with annual counts typically conducted around 1 December using ground surveys and aerial photography. As of 2024, the colony consists of approximately 2,000 breeding pairs, reflecting a modest scale compared to larger Ross Island sites but highlighting its ecological significance in the region's marginal ice zone. The breeding cycle at Cape Royds follows a tightly synchronized annual pattern adapted to the short summer. Penguins begin arriving in mid-October, with males typically preceding females by a few days to reclaim or construct nests from small rock piles amid the volcanic terrain, providing elevation above potential flooding. Egg-laying occurs in late , producing clutches of one to two eggs that are incubated alternately by both parents for 32–34 days; hatching peaks in mid-December, and chicks by late , departing for sea as the ice breaks up. This timing ensures maximal overlap with peak prey availability, though delays in arrival due to heavy can compress the cycle and reduce . Foraging behavior centers on the productive polynya, where open water persists amid surrounding fast ice, supporting dense concentrations of (Euphausia crystallorophias) and Antarctic silverfish (Pleuragramma antarctica). Adults make repeated dives to depths of 20–100 meters during chick-rearing, shifting from primarily krill in early season to a mix including fish as demands increase. Studies from 2021–2023 in the broader region, including sites near Cape Royds, demonstrate flexible effort: penguins extend trip durations and target distant ice edges under high cover but shorten efforts and boost efficiency when ice retreats, adapting to declining concentrations that enhance access to prey patches. Population dynamics at Cape Royds have exhibited long-term stability with fluctuations driven by environmental variability, showing minimal recovery from lows in the early 2000s caused by prolonged blockage from mega-icebergs. Recent trends indicate slight increases or stabilization since 2015, attributed to receding that opens novel foraging grounds and reduces access barriers, as observed in regional monitoring through 2024. However, the colony remains highly vulnerable to intense storms, which can inundate nests and cause near-total breeding failures in affected years.

Other Fauna and Flora

Cape Royds supports a sparse but diverse assemblage of , primarily microscopic soil-dwelling adapted to the harsh conditions. Nematodes, tardigrades, and s are among the dominant terrestrial found in the soils of , including at Cape Royds, where they contribute to nutrient cycling in ornithogenic (penguin-influenced) environments. These organisms, such as the Cryptopygus antarcticus and various nematode , exhibit cryoprotective mechanisms to survive freezing temperatures and . In the lakes, small crustaceans including copepods and ostracods inhabit the benthic zones, particularly in coastal ponds like Pony Lake, where they interact with algal mats under ice cover. Avian species beyond the dominant Adélie penguins are infrequent visitors or occasional breeders at Cape Royds. South Polar skuas (Stercorarius maccormicki) nest sporadically in the vicinity, preying on penguin eggs and chicks during the breeding season. Snow petrels (Pagodroma nivea) are observed near-shore, scavenging or feeding on marine resources, though they do not form large colonies here. No native terrestrial mammals are present, as ecosystems lack land-based mammalian fauna. Marine mammals are also present in the vicinity. Weddell seals (Leptonychotes weddellii) regularly haul out on the fast ice near Cape Royds, particularly non-breeding individuals. The nearby polynya in McMurdo Sound attracts occasional emperor penguins (Aptenodytes forsteri) and leopard seals (Hydrurga leptonyx), which forage in the open water. The flora at Cape Royds is limited to non-vascular cryptogams, reflecting the extreme maritime Antarctic environment. Mosses, such as Bryum argenteum, form small cushions in moist, sheltered soils enriched by seabird activity, demonstrating resilience through desiccation tolerance and rapid photosynthesis upon rehydration. Lichens, including crustose and foliose types like Buellia spp. and Usnea antarctica, dominate exposed rock surfaces, fixing nitrogen and weathering substrates over centuries. Algae, both terrestrial cyanobacteria and freshwater species, thrive in ephemeral streams and lake margins, with Oscillatoriaceae noted in collections from the area. Vascular plants are absent locally, though Antarctica's two native species (Deschampsia antarctica and Colobanthus quitensis) occur elsewhere on the continent. Microbial ecosystems underpin the at Cape Royds, with dominating soils and lake sediments under extreme cold and variable . In ornithogenic soils, diverse bacterial communities, including actinomycetes and species, tolerate cyclic freezing, salinization from , and nutrient pulses from . Endemic psychrophilic and halotolerant in lakes like Lake form dense biofilms during the brief open-water period, driving biogeochemical cycles such as and organic matter decomposition. These microbes exhibit adaptations like proteins and accumulation, enabling persistence in temperatures below -20°C and salinities exceeding 30 ppt.

Human History

Discovery and Naming

Cape Royds was discovered during the British National Antarctic Expedition (1901–04), commonly known as the , led by Captain . The expedition's ship, RRS Discovery, entered on 8 February 1902 after navigating south along the [Ross Island](/page/Ross Island) coast, allowing the first detailed observations of the cape as a prominent dark rock formation marking the western side of the sound. This sighting established Cape Royds as a key coastal feature on [Ross Island](/page/Ross Island), distinguishing it from earlier vague accounts of the region's outline noted by in 1841. The cape was named by Scott in honor of Lieutenant Charles William Rawson Royds, , who served as the expedition's , , and . Royds played a crucial role in the voyage, including leading sledge parties and conducting meteorological observations that contributed to the expedition's scientific output. His and dedication were recognized through this naming, reflecting the tradition of commemorating key personnel in . During the expedition's overwintering at Hut Point from 1902 to 1904, Cape Royds was surveyed and mapped as part of broader efforts to chart Ross Island's western coastline. These surveys highlighted the cape's ice-free nature, with steep dark cliffs rising to about 120 meters, rocky moraines, and a small black sand beach, making it a notable oasis amid the surrounding ice. The mapping efforts provided essential topographical data for future explorations, confirming the area's volcanic origins and accessibility.

Shackleton's Nimrod Expedition

The British Antarctic Expedition of 1907–1909, led by , established its winter base at Cape Royds in February 1908 with the aim of reaching the . The expedition departed from on the ship on December 1, 1907, and arrived at Cape Royds on February 3, 1908, where the team of 15 men unloaded supplies and prepared for overwintering despite challenging ice conditions that prevented further exploration toward King Edward VII Land. Shackleton selected the site for its relative shelter and access to the , as pack ice blocked access to the previously used base at Hut Point. The party endured the Antarctic winter, maintaining routines including meteorological observations from 8 a.m. to 8 p.m. by J.W. Adams and overnight by the night-watchman, while managing limited resources in the isolated valley. Key events centered on transport innovations and the push southward. The expedition imported 10 Manchurian ponies for hauling sledges, a novel approach to supplement manpower, though four died early from ingesting sand and poisoning, leaving four—Quan, Socks, Grisi, and Chinaman—for use; these animals grazed at nearby ponds, contributing to the naming of Pony Lake. On October 29, 1908, Shackleton's Southern Party of four, including , Adams, and Marshall, departed Cape Royds with the ponies pulling loads up to 650 pounds per sledge, navigating crevasses and blizzards. The group achieved a record southern latitude of 88°23'S on January 9, 1909, just 97 nautical miles (112 miles or 180 km) from the Pole, before turning back due to depleting supplies and worsening conditions; ponies were slaughtered for food during the return, with the party reaching the Bluff depot on February 23, 1909, and Cape Royds by March 4, 1909. The returned to evacuate the expedition on February 11, 1909, departing finally on March 21 after resupplying for potential future use. Scientific endeavors at Cape Royds included geological surveys led by Professor T.W. and Raymond Priestley, who examined volcanic formations, collected felspar crystals and pumice from (ascending to the summit at 12,450 feet or 3,794 m on March 10, 1908), contributing to understandings of and as detailed in the expedition's multi-volume reports. Meteorological records captured extreme winds up to 100 mph and temperature variations, providing foundational data on Ross Island's climate. Biological observations by James Murray noted the colony at Cape Royds, one of the southernmost known, with hundreds nesting from October 1908; behaviors such as long overland marches (up to 50 miles) and rookery dynamics were first systematically documented, alongside microscopic freshwater life in local lakes. These findings, published in the expedition's Biology and Geology volumes, advanced knowledge of without reaching the Pole. The Nimrod Expedition's activities at Cape Royds demonstrated the viability of as a staging point for polar travel, influencing subsequent explorations by proving pony-assisted logistics and wintering feasibility in the region. Though short of the Pole, the venture's 88°23'S record and scientific outputs—encompassing over 500 kilometers of new mapping—elevated Shackleton's reputation and laid groundwork for Amundsen's 1911 success, with the team returning safely to in late March 1909.

Cultural and Scientific Sites

Shackleton's Hut

Shackleton's Hut was constructed in February 1908 by members of the British Expedition () at Cape Royds on . The structure was prefabricated in 1907 by Humphreys Limited of , , where it was first assembled for testing before disassembly and shipment to ; the on-site erection took approximately 10 days, followed by three weeks to install insulation. The timber-framed building measures about 10 meters in length by 6 meters in width and features internal matchboard lining for thermal protection against the harsh environment. The hut preserves a remarkable collection of artifacts from the 1908 winter occupation, including unopened canned goods such as , , and , as well as clothing items like woolen mittens and socks, and scientific instruments such as thermometers and barometers left . These items offer insights into early 20th-century logistics and daily life. The site is located at coordinates 77°33′11″S 166°10′06″E. Restoration efforts began in earnest with a 1961 intervention by 's Department of Scientific and Industrial Research to stabilize the structure, followed by comprehensive conservation from 2005 to 2011 led by the Antarctic Heritage Trust (). To highlight its vulnerability and secure funding, the hut was included on the World Monuments Fund's World Monuments Watch lists in 2004, 2006, and 2008, nominated by the Antarctic Heritage Trust. Currently, Shackleton's Hut stands as a structurally sound, weather-tight heritage site, with ongoing annual monitoring and minor maintenance by the Antarctic Heritage Trust to prevent deterioration from environmental factors like wind and salt spray. Access is strictly regulated through guided visits only, emphasizing minimal disturbance to artifacts and the structure, and it remains unoccupied for modern purposes.

Research and Monitoring Stations

Cape Royds serves as a key site for long-term ecological monitoring within the Long Term Ecological Research (LTER) program, funded by the (NSF), which has tracked environmental changes including algal biomass and soil properties since the early 1990s. The colony has been continuously monitored since 1955 through annual population counts conducted under the (USAP), with collaborative efforts involving programs to assess breeding pair numbers and colony dynamics. These counts, typically performed during the austral summer breeding season, provide a unique for studying population fluctuations influenced by conditions and food availability, revealing declines in the 1960s followed by stabilization around 2,000 breeding pairs as of 2024, with partial recovery after the 2005 mega-iceberg event. To enhance monitoring efficiency and enable year-round data collection in remote conditions, automated time-lapse camera systems were deployed at Cape Royds starting in the 2010s as part of the Automated Penguin Monitoring System (APMS) and similar remotely operated networks. These cameras capture breeding behaviors, chick growth, and winter foraging patterns without disturbing the colony, allowing researchers to analyze differential survival rates and environmental impacts over extended periods. Research facilities at the site consist of temporary field camps used seasonally by USAP teams, with no permanent research station to preserve the area's protected status; access is primarily via helicopter from McMurdo Station, approximately 35 km away, utilizing designated pads for safe landings. Ongoing studies emphasize ornithogenic soil analysis, examining nutrient enrichment from penguin guano that shapes chemistry and microbial diversity in the colony vicinity. Recent work on profiles near lake margins has reconstructed penguin recolonization history through geochemical markers like and levels, highlighting how guano influences low-biodiversity, high-nutrient environments. A 2023 study published on GPS-tagged at the Cape Royds used data from 2016–2020, deploying high-resolution GPS-time depth recorders on adult and fledgling Adélie to map dive behaviors and trip durations in the , revealing adaptive strategies tied to body condition and prey distribution. Complementary limnological investigations of lakes like Pony Lake and Blue Lake focus on physicochemical transitions during freeze-thaw cycles and historical assemblages, using samples from early expeditions reanalyzed with modern techniques to detect century-scale shifts.

Protection and Conservation

Antarctic Specially Protected Area

Cape Royds was originally designated as (SSSI) No. 1 in 1975 under Recommendation VIII-4 of the Antarctic Treaty Consultative Meeting to protect its scientific values, and was redesignated as (ASPA) No. 121 in 2002 through Decision 1 (2002). The management plan for ASPA 121 has been revised several times, including in 2009 (Measure 5 (2009)), 2014 (Measure 2 (2014)), and most recently in 2021 (Measure 9 (2021)), to ensure ongoing protection in line with the Protocol on Environmental Protection to the Antarctic Treaty. The protected area encompasses approximately 6,200 hectares, including terrestrial, freshwater, and marine components, to safeguard the site's ecological integrity. Its boundaries extend from Flagstaff Point in the north to Cape Barne in the south along the coastline, incorporating the entire rookery, the southern portion of Pony Lake, and a marine zone reaching 500 meters offshore from the mean . This configuration protects key foraging areas for the penguin colony and prevents encroachment on sensitive habitats. The core purposes of the designation are to preserve the outstanding environmental and scientific values of the area, particularly the large colony (one of the southernmost in ), the unique limnological features of Pony Lake (a rare closed-basin supporting distinct microbial communities), and diverse microbial habitats that serve as type localities for species such as the cyanobacterium . These elements provide critical baselines for studies in , , and microbial , with minimal human disturbance essential to maintaining their natural state. Management of ASPA 121 falls under the , requiring permits for all entry issued by competent national authorities only for compelling scientific or management reasons; recreational visits are prohibited. Designated no-go zones surround active penguin nests and sensitive lake margins to avoid , contamination, or behavioral disruption during the breeding season. Access protocols include restrictions on vehicle use, waste generation, and sampling, with a maximum of 40 people permitted ashore at any one time to limit cumulative impacts. Monitoring and compliance are enforced through annual reporting by permit holders to the Antarctic Treaty Secretariat.

Modern Threats and Management

Climate change presents significant threats to the ecosystems of Cape Royds, particularly through the ongoing decline in concentration in the . Record-low sea ice extents during the winters of 2023 and 2024, with anomalies up to 1.8 million km² below prior averages, have disrupted critical habitats for Adélie penguins, including the third-smallest winter maximum in 2025 (17.81 million km² on September 17, 2025) and a near-record low summer minimum (1.98 million km² on March 1, 2025), with persistent low concentrations in the . These reductions limit access to molting areas during February to March, forcing penguins to expend more energy on foraging and increasing the risk of reduced adult survival rates, as evidenced by correlations between low and lower return rates to breeding colonies like Cape Royds. Additionally, altered patterns linked to warming may increase conductivity in local ponds, such as Pony Lake near Shackleton's Hut, potentially leading to salinization that affects microbial and aquatic communities. Human activities exacerbate these environmental pressures at Cape Royds. , regulated to a maximum of 2000 visitors annually within No. 157, can disturb breeding Adélie penguins and skuas through zodiac landings at Backdoor Bay and pedestrian traffic near colonies. Research operations contribute to localized , including chemical contaminants and waste that alter soil and sediment chemistry, though strict protocols aim to mitigate introductions of non-native species. Cumulative effects from these activities, if unmanaged, could further stress and historic sites. Management strategies focus on minimizing impacts and preserving the site's integrity. The Antarctic Treaty Secretariat's visitor guidelines, implemented via the International Association of Antarctica Tour Operators (IAATO), mandate guided tours, a minimum 5-meter approach to , and zodiac operations confined to designated zones to reduce disturbance. The Antarctic Heritage Trust undertook extensive conservation efforts at Shackleton's Hut during the 2021/22 season, including artefact monitoring, structural assessments, and environmental data collection to combat deterioration from harsh conditions, with continued annual monitoring and maintenance programs through the 2024-25 season. All and litter must be removed, with permits required for entry to protected zones. Looking ahead, monitoring programs track potential tipping points in persistence and ocean warming to inform adaptive strategies. Adélie penguins in the have shown resilience as relative "winners" from receding ice fields, which have facilitated colony expansion by improving access to breeding grounds. However, risks from shifts in prey distributions, such as , due to changing ocean conditions could undermine this advantage, necessitating continued vigilance for population declines.

References

  1. https://www.ats.aq/devAS/Ats/Guideline/f2c01058-4419-40b3-bea0-d18b8a26fb90
  2. https://adam.antarcticanz.govt.nz/nodes/view/20592
  3. https://nzaht.org/conserve/explorer-bases/shackletons-hut/history-of-shackletons-expedition/
  4. https://nzaht.org/conserve/explorer-bases/shackletons-hut/
  5. https://penguinscience.com/daily_journal/
  6. https://www.ats.aq/documents/recatt/att423_e.pdf
  7. https://2009-2017.state.gov/documents/organization/30611.pdf
  8. https://www.env.go.jp/nature/nankyoku/kankyohogo/database/jyouyaku/atcm/atcm_pdf_en/21_en.pdf
  9. https://www.env.go.jp/nature/nankyoku/kankyohogo/database/jyouyaku/aspa/aspa_pdf_en/121.pdf
  10. https://www.ats.aq/devAS/Ats/Guideline/e69a6dcf-4c8e-4da1-9a6d-90df540fff8f
  11. https://www.wgtn.ac.nz/antarctic/publications/antarctic-data-series/ADS10.pdf
  12. https://tc.copernicus.org/articles/15/4999/2021/tc-15-4999-2021.pdf
  13. https://journals.ametsoc.org/view/journals/apme/32/12/1520-0450_1993_032_1867_arsopb_2_0_co_2.pdf
  14. https://www.sciencedirect.com/science/article/pii/S0923250810002810
  15. https://www.researchgate.net/publication/223452945_Chemical_characterization_of_dissolved_organic_material_in_Pony_Lake_a_saline_coastal_pond_in_Antarctica
  16. https://academic.oup.com/book/2631/chapter/143029537
  17. https://www.climate.gov/news-features/event-tracker/2024-antarctic-sea-ice-winter-maximum-second-lowest-record
  18. https://nsidc.org/arcticseaicenews/2023/10/antarctic-sea-ice-near-historic-lows/
  19. https://nsidc.org/arcticseaicenews/2024/10/2024-antarctic-winter-maximum-sea-ice-extent-second-lowest-record/
  20. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2023JC020134
  21. https://ui.adsabs.harvard.edu/abs/1962GMS.....7...40T/abstract
  22. https://agupubs.onlinelibrary.wiley.com/doi/10.1029/AR048p0018
  23. https://nipr.repo.nii.ac.jp/record/88/files/KJ00000000940.pdf
  24. https://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1336&context=geosciencefacpub
  25. https://pubs.geoscienceworld.org/gsl/books/edited-volume/2349/chapter/132277245/Chapter-5-2b-Erebus-Volcanic-Province-petrology
  26. https://www.sciencedirect.com/science/article/abs/pii/S0341816222000558
  27. https://core.ac.uk/download/pdf/41336077.pdf
  28. https://www.sciencedirect.com/science/article/abs/pii/S0025322799000614
  29. https://nipr.repo.nii.ac.jp/record/2532/files/KJ00002368069.pdf
  30. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=112995
  31. https://www.lyellcollection.org/doi/10.1144/m55-2018-80
  32. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=112825
  33. https://nora.nerc.ac.uk/id/eprint/526188/1/bulletin29_04.pdf
  34. https://science.cen.ulaval.ca/warwickvincent/PDFfiles/102-James.pdf
  35. https://www.quekett.org/wp-content/uploads/2017/02/murray-antarctic-rotifera.pdf
  36. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=123610
  37. https://aslopubs.onlinelibrary.wiley.com/doi/pdf/10.4319/lo.1962.7.1.0036
  38. https://www.lpi.usra.edu/meetings/polar2003/pdf/8039.pdf
  39. https://mcm.lternet.edu/
  40. https://ir.canterbury.ac.nz/bitstream/handle/10092/11957/Christenson_Thesis.pdf?sequence=1
  41. https://www.comnap.aq/s/Limno-Terrestrial-Microfauna.pdf
  42. https://aslopubs.onlinelibrary.wiley.com/doi/10.1002/lol2.10200
  43. https://www.cambridge.org/core/journals/antarctic-science/article/100-years-on-a-reevaluation-of-the-first-discovery-of-microfauna-from-ross-island-antarctica/029024D965DB82E7D9692B9F90D8C17E
  44. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=123650
  45. https://documents.ats.aq/recatt/Att181_e.pdf
  46. https://www.algaebase.org/search/species/detail/?species_id=66991
  47. https://mcm.lternet.edu/content/pony-lake-ross-island
  48. https://gazetteer.linz.govt.nz/place/55683
  49. https://academic.oup.com/femsec/article/76/3/401/486873
  50. https://www.cambridge.org/core/journals/antarctic-science/article/physicochemical-and-biological-dynamics-in-a-coastal-antarctic-lake-as-it-transitions-from-frozen-to-open-water/02C9578A9062BFEC4A2C1FC2C4E95957
  51. https://www.researchgate.net/publication/259437032_Physicochemical_and_biological_dynamics_in_a_coastal_Antarctic_lake_as_it_transitions_from_frozen_to_open_water
  52. https://people.uncw.edu/emslies/documents/Antarcticlakesreading.pdf
  53. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=124219
  54. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=1056
  55. https://www.sciencedirect.com/topics/earth-and-planetary-sciences/mcmurdo-sound
  56. https://aslopubs.onlinelibrary.wiley.com/doi/pdf/10.4319/lo.1972.17.3.0356
  57. https://nipr.repo.nii.ac.jp/record/1657/files/KJ00000012289.pdf
  58. https://www.tandfonline.com/doi/pdf/10.1080/00288306.1969.10431107
  59. https://www.sciencedirect.com/science/article/pii/S1873965218300264
  60. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=114481
  61. https://data.aad.gov.au/aadc/gaz/display_name.cfm?gaz_id=132582
  62. https://www.antarcticglaciers.org/glacial-geology/glacial-landsystems/glacial-landsystems-on-james-ross-island/
  63. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2011RG000371
  64. https://blogs.oregonstate.edu/seabirdoceanographylab/2024/02/16/notes-from-the-field-ross-island-antarctica/
  65. https://www.usap.gov/sciencesupport/scienceplanningsummaries/2024_2025/results.cfm?formAction=detail&ID=2893
  66. https://www.nature.com/articles/s41598-020-63875-y
  67. https://link.springer.com/article/10.1007/s00227-024-04575-3
  68. https://pmc.ncbi.nlm.nih.gov/articles/PMC10655226/
  69. https://cmr.earthdata.nasa.gov/search/concepts/C1214591191-SCIOPS.html
  70. https://pmc.ncbi.nlm.nih.gov/articles/PMC4109451/
  71. https://people.uncw.edu/emslies/documents/LectureXAntarcticlakesfall2023_000.pdf
  72. https://www.nzbirdsonline.org.nz/species/south-polar-skua
  73. https://www.ecfr.gov/current/title-45/subtitle-B/chapter-VI/part-670
  74. https://www.cambridge.org/core/journals/antarctic-science/article/molecular-support-for-pleistocene-persistence-of-the-continental-antarctic-moss-bryum-argenteum/654CD1AE149524788721B5399C0164AA
  75. https://people.uncw.edu/emslies/documents/Smyklaetal.2011lichensofRossSea.pdf
  76. https://cmr.earthdata.nasa.gov/search/concepts/C1214620882-SCIOPS.html
  77. https://www.researchgate.net/publication/231803050_Molecular_support_for_Pleistocene_persistence_of_the_continental_Antarctic_moss_Bryum_argenteum
  78. https://journals.asm.org/doi/pdf/10.1128/am.11.2.116-121.1963
  79. https://cdnsciencepub.com/doi/10.1139/W08-126
  80. https://www.spri.cam.ac.uk/museum/exhibitions/charlesroyds/
  81. https://nzaht.org/conserve/explorer-bases/shackletons-hut/introduction-to-shackletons-hut/
  82. https://www.polartours.com/highlights/cape-royds
  83. https://www.biodiversitylibrary.org/bibliography/22427
  84. https://archiveshub.jisc.ac.uk/data/gb15-sirraymondpriestley/sirraymondpriestley/britishantarcticexpedition%2C1907-1909
  85. https://www.coolantarctica.com/gallery/travel/56.php
  86. https://www.antarctic-circle.org/huts.htm
  87. https://www.ats.aq/devPH/en/apa-database/94
  88. https://www.wmf.org/projects/scotts-hut-and-explorers-heritage-antarctica
  89. https://mcm.lternet.edu/content/algal-microbial-mat-biomass-measurements-mcmurdo-dry-valleys-and-cape-royds-antarctica-1994
  90. https://par.nsf.gov/servlets/purl/10543099
  91. https://www.antarctica.gov.au/magazine/issue-31-december-2016/people/creative-solutions-to-antarctic-challenges/
  92. https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0193532
  93. https://penguinscience.com/wp-content/uploads/reprints/Lescroel_etal_2023_ProcRoySocB.pdf
  94. https://www.ats.aq/devAS/Meetings/Measure/422
  95. https://www.ats.aq/devAS/Meetings/Measure/718
  96. https://documents.ats.aq/recatt/att682_e.pdf
  97. https://nsidc.org/sea-ice-today/analyses/antarctic-sea-ice-maximum-settles-third-place
  98. https://nsidc.org/sea-ice-today/analyses/antarctic-sea-ice-minimum-hits-near-record-low-again
  99. https://nzaht.org/antarctic-conservation-season-update-june-2022/
Add your contribution
Related Hubs
User Avatar
No comments yet.