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Ross Sea

The Ross Sea is a vast, deep bay in the southwestern Pacific sector of the , bounded by to the east, to the west, and the to the south. This region, extending northward from the , features depths exceeding 1,000 meters in places and is influenced by seasonal formation, polynyas, and that drive its exceptional primary productivity—the highest in the . The adjacent , 's largest, covers approximately 487,000 square kilometers with thicknesses ranging from 300 to 1,200 meters, acting as a floating barrier that modulates and ice dynamics. Ecologically, the Ross Sea supports dense concentrations of , penguins, seals, whales, and diverse benthic communities, making it a with relatively low human impact compared to other ocean regions. In 2017, the Ross Sea region was established, encompassing 1.55 million square kilometers and prohibiting commercial fishing across 1.1 million square kilometers to safeguard this productive ecosystem from and support scientific research into climate-driven changes.

Geography

Location and Boundaries

The Ross Sea constitutes a deep embayment of the penetrating the Antarctic continental margin in the Pacific-Antarctic sector. It lies between to the west and to the east, encompassing longitudes from approximately 165° E to 155° W. The western boundary follows the irregular coastline of , starting from at about 71° S, 170° E, and extending southward through features such as the Scott Coast and Shackleton Coast. The eastern boundary is formed by the Edward VII Peninsula and the Siple Coast, reaching Cape Colbeck near 77° 30' S, 157° W, marking the transition to the . The southern boundary is delineated by the calving front of the , which extends roughly from 160° W to 170° W at latitudes around 78° S, representing the northern edge of the world's largest floating ice shelf. To the north, the Ross Sea merges openly with the , with its extent conventionally associated with the Antarctic south of approximately 60° S within the 160° E to 150° W longitudinal sector. This configuration positions the Ross Sea as the southernmost reach of open ocean waters, facilitating unique oceanographic and ecological dynamics.

Physical Features and Bathymetry

The Ross Sea constitutes a large embayment of the , bounded to the west by the coast and to the east by , forming a triangular region that extends northward from the to approximately 70°S latitude. Its , the largest and widest in , encompasses roughly 466,000 km² and underlies much of the sea floor south of the shelf break. This shelf is partially overlain by the expansive , which covers an area of about 487,000 km² and influences surface physical characteristics through seasonal formation and persistent fast ice zones. Bathymetrically, the Ross Sea shelf exhibits rugged topography characterized by deep troughs, elevated banks, and sediment-filled , with an average depth of approximately 685 m. Depths generally range from less than 400 m over low-relief banks in the western sector to over 900 m along the coast south of 74°S and in troughs such as the Drygalski Trough. The eastern shelf features broad troughs reaching 400–700 m, while the Central , a prominent bathymetric low south of major western Ross Sea troughs, exceeds 1,000 m in places. These features result from glacial erosion and deposition, creating a of depressions and highs that control local circulation and distribution. Beyond the shelf break, which lies at depths of around 500–600 m, the seafloor descends steeply into the adjacent of the , reaching depths exceeding 3,000 m. Key bathymetric highs include Pennell Bank and Iselin Bank, which rise to shallow depths of 200–300 m and act as barriers to cross-shelf flow, while sediment-laden basins like the Joides Basin accommodate thicker accumulations of glacial marine deposits. Recent compilations of multibeam and single-beam data have refined these contours, revealing previously unmapped cavities beneath ice shelves and highlighting the shelf's overall deeper profile compared to global averages, attributable to isostatic depression from ice loading.

History of Exploration

Discovery by James Clark Ross

The British Antarctic Expedition of 1839–1843, commanded by Captain James Clark Ross aboard HMS Erebus and HMS Terror, marked the first systematic penetration into Antarctic waters south of the pack ice. Ross, selected for his prior Arctic experience including the location of the North Magnetic Pole in 1831, aimed primarily to investigate terrestrial magnetism and locate the South Magnetic Pole. The ships, reinforced with iron plating to withstand ice pressure, departed England in September 1839, overwintered in Hobart, Tasmania, in 1840, and re-entered Antarctic waters in late 1840 after surveying sub-Antarctic islands. After navigating heavy pack ice for weeks, the expedition broke into open water at approximately 5 a.m. on January 9, 1841, at 71°15'S, revealing the vast expanse later named the Ross Sea in honor of its discoverer. This breakthrough provided the first recorded access to a major embayment in the Antarctic continental margin, extending access southward toward the magnetic pole's calculated position. Two days later, on , the ships sighted extensive land to the southwest, initiating further exploration. On January 12, 1841, Ross's party landed on Possession Island (71°56'S, 171°7'W), claiming the newly discovered territory for and naming features including the adjacent after . Continuing south, the expedition encountered the Great Ice Barrier—now known as the —on January 13, blocking further progress at about 78°10'S despite attempts to sledge over its surface. These observations, documented in Ross's voyage narrative, established the Ross Sea region's ice-free oceanic gateway and its formidable barrier, influencing subsequent endeavors. The discovery relied on empirical navigation amid variable ice conditions, with no prior European sightings of this sector confirmed in expedition logs or contemporary records.

Expeditions of the Heroic Age

The British National Antarctic Expedition, led by Robert Falcon Scott aboard the RSS Discovery, reached McMurdo Sound in the Ross Sea on February 3, 1902, after departing Lyttelton, New Zealand, on December 21, 1901. The expedition established winter quarters at Hut Point on Ross Island, conducting extensive sledge journeys that mapped over 500 miles of the Ross Ice Shelf's edge and interior, including the first ascent of Mount Erebus on March 10-11, 1908, though this was during a later effort; during Discovery, they reached a furthest south of 82°17'S on December 30, 1903. The ship became trapped in ice from February 1902 until dynamite-assisted freeing on February 16, 1904, enabling departure after comprehensive magnetic, meteorological, and biological observations in the region. Ernest Shackleton's British Antarctic Expedition on the arrived at on Ross Island on February 1, 1908, following departure from Lyttelton on January 1, 1908. The team erected a prefabricated hut there and launched a polar party that achieved 88°23'S on January 9, 1909, 112 miles short of the , while surveying the route from the Ross Sea inland. Additional efforts included geological collections from the Royal Society Range and biological studies of colonies at Cape Royds, with the expedition departing the ice on March 1, 1909, after enduring fuel shortages and harsh conditions. In the 1910-1912 season, competing efforts converged on the Ross Sea: Scott's British Expedition () established base at on [Ross Island](/page/Ross Island) on January 15, 1911, after sailing from Lyttelton on November 29, 1910, and reached the on January 17, 1912, only to find Roald Amundsen's party had arrived December 14, 1911. Amundsen's Expedition () had landed at the Bay of Whales on January 14, 1911, selecting it as the southernmost accessible site in the Ross Sea, 60 nautical miles closer to the pole than bases, facilitating dog-sled depots and the successful polar attainment. Scott's return party perished from starvation and exposure, with the last diary entry dated March 29, 1912, recovered May 1912; Amundsen's team safely retrieved supplies and departed February 1912. Shackleton's included a Ross Sea party aboard , landing at on January 16, 1915, to lay depots along the , but the ship broke free prematurely, stranding 10 men for nearly two years with three fatalities from and before relief in January 1917. These operations, though at the Heroic Age's close, underscored the Ross Sea's role as a logistical gateway, with surviving huts at Hut Point, , and preserving artifacts like provisions and equipment from these ventures.

Post-War Research and Modern Surveys

Following , the initiated in 1946–1947, a large-scale naval expedition led by that conducted aerial photographic surveys and initial mapping across Antarctic regions, including parts of the Ross Sea to support strategic and scientific reconnaissance. This effort laid groundwork for subsequent operations, culminating in I during 1955–1956, which focused on the Ross Sea by establishing on and Little America V on the , involving ice reconnaissance, topographic surveys, and logistical setups essential for year-round research access. The (IGY) of 1957–1958 marked a surge in coordinated international research in the Ross Sea, with constructing near in January 1957 to facilitate seismic, geodetic, and meteorological surveys across 11 scientific fields. teams at McMurdo expanded glaciological and oceanographic studies, including measurements of warm-water penetration into the Ross Sea during austral summer, while geological mapping targeted coastal sites for understanding continental structure. These efforts, supported by overflights and ship-based sampling, produced foundational data on sea floor topography and ice dynamics, transitioning exploration from heroic-era sledge traverses to systematic scientific investigation. Post-IGY activities under the 1959 Antarctic Treaty emphasized sustained surveys, with U.S. Geological Survey teams conducting and sampling in the Ross Sea region during the 1960s to map basement structures and stratigraphic layers. New Zealand's RV performed multibeam bathymetric surveys in 2006–2007, collecting over 100,000 km² of high-resolution seafloor data to refine contours of the continental shelf and identify previously unmapped features like troughs and basins. Such mapping updated earlier sparse soundings, aiding interpretations of paleoceanographic conditions and grounding lines. In the , multinational efforts have integrated advanced technologies for Ross Sea surveys, including the 2018 RV OGS Explora expedition, which deployed autonomous underwater vehicles during ice-free conditions to profile masses and ice-ocean interactions across under-sampled shelf areas. The ANDRILL program's 2006–2007 project cored 1,138 meters into the seafloor, revealing Miocene-to-recent sedimentary records of variability. These surveys, contributing to the Bathymetric Chart of the (IBCSO v2, released 2022), have resolved fine-scale landforms with resolutions down to 100–200 meters, enhancing models of dense shelf formation and glacial history.

Geology

Continental Shelf and Basement Structure

The Ross Sea continental shelf represents one of the widest and deepest such features surrounding , spanning an area exceeding 460,000 km² with water depths typically ranging from 300 m near the coast to over 1,000 m along the inner shelf, and a shelf break occurring at approximately the 700 m isobath. This overdeepened profile, characterized by landward-dipping bathymetry, results from repeated glacial erosion by ice streams during ice sheet advances, which sculpted major troughs such as the Drygalski, Pennell, and Joides basins, interspersed with shallower banks like Pennell and Crary-Mawson. The shelf's broad expanse, extending up to 900 km seaward in places, facilitated extensive grounding of the during glacial maxima, with sediment thicknesses accumulating to several kilometers in depocenters. Beneath the shelf lies a crystalline composed primarily of early post-orogenic sedimentary rocks intruded by mid- to Cretaceous granitoids, alongside metamorphic and granitic units akin to those exposed in adjacent and . Geophysical surveys, including gravity inversions and magnetic data, reveal a complex topography shaped by Cretaceous-Neogene extension associated with the West Antarctic Rift System, featuring fault-bounded basins up to 4,500 m deep below (e.g., Western Ross Basin, approximately 300 km by 600 km in extent) and segmented highs with minimal sedimentary overburden (0–500 m). In the eastern Ross Sea, pre-Miocene highs like the Central High formed structural ramps that influenced early paleobathymetry, transitioning from deep basins to a modern configuration through tectonic subsidence and glacial modification. The basement extends continuously beneath the adjacent Ross Ice Shelf, where a prominent Mid-Shelf High—roughly 650 km long and over 150 km wide in segments—trends northward into the Ross Sea's Central High and Victoria Land Basin, overlain by thin non-magnetic sediments indicative of extended continental crust. These structures, delineated via airborne magnetics and gravity data from projects like ROSETTA-Ice, highlight short-wavelength anomalies corresponding to rift-related troughs and highs, with sediment-filled grabens reaching 2,500 m depth in localized areas. Such features underscore the Ross Sea's role as a rifted margin, where basement architecture controls sediment distribution and ice sheet dynamics, with denser modeling confirming variable crustal densities (2.7–3.0 g/cm³) across basins.

Stratigraphy and Sedimentology

The Ross Sea underlies several rift-related sedimentary basins, including the Basin, Central , and Eastern , with sediment thicknesses reaching up to 4–5 km above an acoustic basement of inferred age. Seismic delineates regionally correlatable sequences, such as Ross Sea Seismic Sequences (RSS-1 to RSS-8) in the northwestern Central , bounded by high-amplitude reflectors marking al unconformities linked to glacial and relative sea-level changes. Lower sequences (e.g., RSS-1 to RSS-3) comprise syn-rift to early post-rift fill from the to Eocene, dominated by sandstones, shales, and deposited in fluvial-deltaic to shallow-marine environments prior to widespread glaciation. Overlying Miocene and younger strata (e.g., RSS-4 to RSS-8) record the onset of the around 34 Ma, transitioning to glacial-influenced deposition with progradational parasequences of diamictites, mudstones, and sandstones reflecting repeated ice-sheet advances and retreats. Site U1521 cores reveal early to middle facies alternating between subglacial tills and open-marine silts, indicating dynamic ice grounding and plumes during a period of relative warmth. Pliocene-Pleistocene sections exhibit thicker accumulations of grounded ice-sheet diamictons during glacial maxima, with erosional truncation surfaces at sequence boundaries corresponding to lowered sea levels and ice-shelf grounding. drapes consist of thin hemipelagic muds with ice-rafted debris, accumulating at rates of 1–5 cm/kyr in depocenters. Sedimentological characteristics are dominated by terrigenous siliciclastics, with diamictons—poorly sorted, matrix-supported mixtures of clay to boulder-grade material—comprising the bulk of glacial sequences and evidencing subglacial , debris flows, and ice-berg rainout. Gravel fractions in late sediments derive primarily from granitic and metamorphic sources in the and local basement, with low volcanic content reflecting limited input from McMurdo Volcanic Group. Clay mineral assemblages feature and , indicative of physical under periglacial conditions, while surface sediments display poor sorting (sorting coefficient >2 φ) and high fines content (>50% ), signifying low-energy, acoustically damped depositional environments in protected basins. Sediment provenance and grain-size distributions further highlight provenance from proximal ice streams, with enhanced accumulation during ice-sheet maxima driven by hyperpycnal flows and shelf-edge deltas.

Geologic Drilling and Subsurface Insights

The Antarctic geological drilling program (ANDRILL) conducted key subsurface investigations in the Ross Sea region, recovering sediment cores that extend back into the Miocene and reveal cycles of ice sheet advance, retreat, and associated depositional environments. At the McMurdo Ice Shelf (MIS) site AND-1B, drilling in 2006 penetrated 1284.87 meters of sediment beneath the ice shelf, providing a continuous Late Neogene record spanning approximately the last 14 million years, with lithofacies dominated by diamictites indicative of repeated glacial erosion and subglacial deposition during grounded ice advances. The core documents at least 40 grounding events of the ice sheet, with fining-upward sequences reflecting transitions from proximal glacial settings to distal marine environments during interglacials. In the Southern McMurdo Sound (SMS) project, the AND-2A borehole reached 1138.54 meters in 2007, offering high-resolution stratigraphic control tied to regional seismic profiles and revealing early Miocene ice dynamics through heavy mineral provenance analysis. Sediments from 17–14 million years ago show provenance shifts from local volcanic sources to recycled sedimentary material, signaling the onset of a dynamic East Antarctic Ice Sheet with periodic marine-based expansions into the Ross Embayment. Upper core units include volcanic tephra layers and biosiliceous oozes, indicating episodic open-water conditions and influence from nearby McMurdo Volcanic Group activity on subsurface sediment composition. International Ocean Discovery Program (IODP) Expedition 374 in 2018 targeted Ross Sea shelf sites to probe grounding line evolution, with Site U1521 in the central Ross Sea recovering cores that document ice sheet-ocean interactions through analysis of glacial tillites and mudstones. These reveal a shift from temperate, wet-based glaciation in the early to colder, polythermal conditions by the middle , with seismic integration showing basement-involved faulting and subsidence influencing sediment thickness and ice loading responses. Site U1524, on a distal shelf , intersected ~500 meters of and provided evidence of contourite drifts overlying glacial sequences, highlighting subsurface hydrodynamic influences on post-glacial . Collectively, these efforts illuminate a subsurface characterized by rift-related basins filled with syn- to post-glacial strata, where volcanic basement rocks interfinger with terrigenous clastics eroded from the . Heat flow measurements from AND-1B indicate low geothermal gradients (~40–50 mW/m²), consistent with thick sedimentary infill and under ice loading, while pore pressure data suggest overpressured zones in deeper glacial tills, informing models of subglacial hydrology and deformation. Such insights challenge earlier views of a stable , demonstrating instead recurrent instabilities tied to and ocean warming thresholds.

Oceanography

Circulatory Patterns and Water Masses

The ocean circulation in the Ross Sea is primarily driven by a combination of wind forcing and density gradients, featuring inflows of relatively warm Deep Water () onto the continental shelf through major bathymetric troughs, including the Drygalski Trough in the southwest and the Glomar Trough in the east. This intrusion supports a persistent gyral system comprising two cyclonic eddies and three anticyclonic features, with overall anticyclonic circulation dominating the western sector and facilitating cross-shelf exchange. Transports within these features increase substantially during winter, from approximately 1–2 in summer to higher values driven by brine rejection and cooling, which enhance density-driven outflows of shelf waters along the slope. Key water masses include Antarctic Surface Water (AASW), occupying the upper layer with neutral density (γn) below 28.00 kg m−3, temperatures ranging from −2.3°C to 2°C, and salinities of 33–34.4, formed by sea ice melt and inflowing via the Ross Gyre to modulate surface stratification. Lower Circumpolar Deep Water (LCDW), a subset of CDW, enters at mid-depths with temperatures exceeding 1.5°C, salinities above 34.70, and γn of 28.00–28.27 kg m−3, providing heat and nutrients that mix with AASW to produce Modified CDW (MCDW) characterized by 30–70% LCDW content and regional variations in composition (e.g., more AASW influence in the east). Dense shelf waters, such as High Salinity Shelf Water (HSSW) with salinities over 34.70, temperatures ≤ −1.85°C, and γn above 28.27 kg m−3, form through brine exclusion in coastal polynyas like Terra Nova Bay, while Low Salinity Shelf Water (LSSW) arises from melting with salinities ≤ 34.70. These shelf waters mix with MCDW to generate (AABW), which outflows at rates of 3–4 Sv through the same troughs, ventilating the deep and contributing to global . Deep Ice Shelf Water (DISW), a variant of dense shelf water, emerges from sub-ice shelf circulation with elevated densities, further influencing bottom outflows. Over recent decades, these masses have shown trends of AASW freshening (ΔS ≈ 0.05–0.3) and LCDW warming/salinification (Δθ ≈ 0.3–0.4°C, ΔS ≈ 0.03–0.04), strengthening the pycnocline while shifting AABW toward lower-salinity types.

Polynyas, Sea Ice Formation, and Dense Shelf Water

The Ross Sea polynyas, particularly the expansive Ross Ice Shelf Polynya, emerge as persistent openings in the sea ice cover, driven primarily by strong katabatic winds originating from the Antarctic continent that advect newly formed ice offshore while exposing underlying ocean surfaces to freezing air temperatures. These features, including smaller ones like the McMurdo Sound and Terra Nova Bay polynyas, span areas that vary interannually but collectively support high rates of sea ice production, with the Ross Ice Shelf Polynya alone accounting for substantial winter ice export. Wind forcing and coastal topography enhance polynya persistence by promoting divergence of ice floes and limiting refreezing, resulting in open water fractions that can exceed 50% of the regional sea ice zone during peak winter conditions. Sea ice formation within these polynyas initiates as frazil ice crystals in supercooled surface waters, rapidly aggregating into pancake and consolidated under turbulent conditions induced by winds exceeding 10-15 m/s. Brine rejection during this process excludes salt from the growing , elevating the of residual shelf waters by up to 0.5-1 psu over the winter season, which, combined with near-freezing temperatures around -1.9°C, generates dense shelf water (DSW) through convective overturning that penetrates to the seafloor at depths of 500-1000 m. Annual production in the Ross Sea polynyas is estimated at 1-2 million km², far exceeding surrounding pack zones, due to the repeated exposure of to atmospheric cooling without insulating cover. The DSW formed exhibits densities exceeding 27.8 kg/m³, enabling it to cascade downslope at the continental shelf break, where it mixes with Circumpolar Deep Water to form (AABW), contributing 20-40% of global AABW volume from Ross Sea sources alone. This dense water export ventilates the deep ocean, influencing meridional overturning circulation, though recent observations indicate variability linked to atmospheric teleconnections, with reduced production in warmer years due to diminished formation and buildup. Convective plumes in polynyas sustain vertical mixing rates of 10-100 m/day, preventing and facilitating upwelling that supports post-winter , while also exporting heat and freshwater anomalies basin-wide.

Climate Dynamics

Historical Climate Patterns

Paleoclimate reconstructions for the Ross Sea region rely primarily on and proxies, revealing variability in temperature, extent, and ocean circulation over the past several millennia. The ice core, spanning approximately 83,000 years, provides a continuous record from an ice dome between paleo-ice stream troughs in the Ross Sea, capturing shifts in accumulation and isotopic signatures indicative of regional climate. Sediment cores from the western Ross Sea, such as those from the JOIDES Trough, indicate that warm Circumpolar Deep Water (CDW) intruded onto the shelf shortly after the around 20,000 years ago, facilitating initial retreat amid deglacial warming. During the Holocene, the Ross Sea experienced fluctuating ice cover and oceanographic conditions. Mid-Holocene records from Robertson Bay sediments show persistent in the northwestern Ross Sea around 5,000 calibrated years (cal kyr ), contrasting with the broader Antarctic warming during the and suggesting localized persistence of cold conditions influenced by shelf and ice dynamics. Later Holocene evidence points to widespread instability of the , with collapse events linked to atmospheric warming reconstructed from nearby ice cores, occurring in phases that align with reduced and increased open water. Over the past 2,700 years, the Ross Sea Dipole—a pattern of opposing climate anomalies—has driven variability in temperature, snow accumulation, and . Ice core data from the region document colder-than-average temperatures and expanded in the western Ross Sea during the (roughly 1400–1850 CE), while the eastern sector saw relative warming, highlighting spatial heterogeneity tied to rather than uniform hemispheric cooling. Oxygen isotope records from multiple Ross Sea drainage ice cores over the last 1,400 years further reveal decadal- to centennial-scale fluctuations, with δ¹⁸O variations reflecting source region temperature changes in . These patterns underscore the Ross Sea's sensitivity to both local ice-ocean interactions and broader forcing, with sediment proxies confirming episodic as a key driver of shelf warming episodes.

Observed Changes and Future Projections

Satellite observations indicate that extent in the Ross Sea sector exhibited a statistically significant increase from 1979 to 2014, with a trend that could not be explained by natural variability alone, contrasting with declines in other regions. This expansion has been attributed to regional wind patterns enhancing ice export and formation, alongside increased from freshwater inputs. However, broader reached its third-lowest winter maximum on record in 2025 at 17.81 million square kilometers, though the Ross Sea showed relatively rapid rebound in extent during the preceding months due to slower . Instrumental records and proxy reconstructions reveal atmospheric warming across the Ross Sea, with declining snow accumulation in the eastern sector and variable trends in the west, alongside overall positive temperature anomalies since the mid-20th century. Oceanographic measurements document persistent freshening of Ross Sea shelf waters since the , driven by enhanced melting of West ice shelves and glaciers, which alters buoyancy and dense water formation. Basal melting beneath the has intensified, with advected heat from surface waters increasing over the past four decades, as evidenced by direct observations of warmer Deep Water () intrusions. Glacier terminus positions along the western Ross Sea coast have retreated variably between 71°S and 78°S from the 1940s to 2010s, serving as a for reduced snowfall accumulation amid regional warming. areas in the Ross Sea, such as the Terra Nova Bay polynya, exhibit a 16-year oscillatory cycle in extent, influencing sea ice production and linked to large-scale atmospheric forcing like the Southern Annular Mode (). Climate models project a robust decline in Ross Sea sea ice concentration and seasonal volume under future scenarios, potentially disrupting and budgets and reducing dense shelf water export. High-resolution simulations indicate that strengthened winds and elevated air temperatures could enhance activity and ice shelf basal melt, though surface air warming may remain locally subdued compared to other sectors. Projections suggest increased upwelling and ocean transport beneath the , heightening instability risks for the margin by the end of the century, with implications for global . These forecasts, however, diverge from historical Ross Sea gains, highlighting model limitations in capturing regional wind-driven variability and effects. Future dynamics may intensify under positive SAM phases, boosting production short-term but yielding net losses from overall warming.

Biology and Ecology

Biodiversity and Habitat Types

The Ross Sea encompasses diverse marine , including regions with shallow banks and deep troughs, continental slopes, abyssal plains, pelagic zones, benthic environments, and sea -associated microhabitats. These features support a range of ecological niches from coastal neritic areas to open pack zones. Pelagic habitats in the Ross Sea are characterized by high primary productivity driven by phytoplankton blooms, which form the base of the and contribute approximately 28% of the Southern Ocean's total production. Mesozooplankton and dominate the mid-trophic levels, with serving as a critical link to higher predators. The region hosts at least 95 fish species, including and , adapted to varying water masses and depths. Benthic communities exhibit variability across shelf, slope, and abyssal environments, with macro- and mega-faunal assemblages influenced by seafloor , depth, and organic input from surface waters. Strong benthic-pelagic coupling enhances in shelf areas, supporting diverse such as sponges, bryozoans, and polychaetes. Seafloor video surveys from 270 to 1173 meters depth reveal distinct megafaunal assemblages tied to heterogeneity. Sea ice habitats include surface ponds, slush layers, and internal ice strata, fostering specialized biota like and associated grazers that contribute to annual productivity cycles. These under-ice communities link to broader ecosystems via seasonal melt and support cryopelagic . Coastal and pack ice zones further enhance diversity, accommodating ice-obligate organisms. Overall biodiversity is among the highest in the Southern Ocean, with the Ross Sea recognized as a hotspot due to its productivity and low human impact. It sustains at least 10 marine mammal species, including Weddell seals and minke whales, and several seabird species, notably Adélie penguins (38% of global population) and emperor penguins (26% of global population). This richness stems from physical oceanographic features like polynyas that promote nutrient upwelling and ice-free conditions for foraging.

Key Species Interactions and Food Webs

The Ross Sea continental shelf ecosystem features a food web structured around mid-trophic keystone species Antarctic silverfish (Pleuragramma antarcticum) and crystal krill (Euphausia crystallorophias), contrasting with the Antarctic krill (Euphausia superba)-dominated systems elsewhere in the Southern Ocean. Primary production, primarily from seasonal phytoplankton blooms transitioning from colonial haptophyte Phaeocystis antarctica in early spring to diatoms later in the season, forms the basal energy source, fueling krill grazing and subsequent trophic transfers. This progression influences grazer assemblages, with crystal krill exhibiting high biomass over the shelf and serving as a critical link to higher predators. Antarctic silverfish occupy a pivotal role, preying on smaller zooplankton and fish while being consumed by apex predators such as Weddell seals (Leptonychotes weddellii), Adélie penguins (Pygoscelis adeliae), and minke whales (Balaenoptera bonaerensis). Intense predation pressure on crystal krill, particularly by Adélie penguins and Antarctic silverfish, results in their seasonal depletion, shaping foraging behaviors and community dynamics in neritic waters. Baleen whales, including humpback (Megaptera novaeangliae) and minke species, target aggregations of crystal and Antarctic krill near ice edges, with observed declines in krill surface abundance correlating to increased whale and penguin predation during austral summer. Trophic interactions exhibit a "wasp-waist" structure, characterized by a narrow mid-trophic bottleneck of high-biomass and sustaining diverse top predators, which in turn promotes efficient carbon export to deeper waters. Adélie penguin reproductive success and foraging strategies respond to these dynamics, with evidence of trophic cascades where abundance modulates penguin reliance on alternative prey amid fluctuating availability. Benthic-pelagic coupling involves minor but notable contributions from shelf , grazed by like (Dissostichus mawsoni), which themselves face predation from Weddell seals and emperor penguins ( forsteri). Regional variations persist, with western Ross Sea webs showing pronounced on by penguins and , while eastern areas emphasize krill-mediated pathways; these differences arise from oceanographic gradients influencing primary productivity and species distributions. Overall distribution forms a partially inverted pyramid, peaking at lower-mid trophic levels dominated by (estimated at 100-300 million tonnes shelf-wide) and , underscoring the ecosystem's resilience to perturbations at basal levels but to mid-trophic . predators, including and whales, exhibit spatial overlap with krill swarms, driving concentrated predation events that deplete local densities and alter patterns.

Human Activities

Commercial Fisheries

Commercial fishing in the Ross Sea region primarily targets (Dissostichus mawsoni) using longline methods, with operations classified as exploratory under CCAMLR Conservation Measure 41-09. The fishery commenced in the late , with initial catches of approximately 40 tonnes in the 1997–98 season, expanding to over 3,000 tonnes by 2005–06 as vessel numbers increased to support stock assessments and . Activities are confined to specific statistical subareas, notably 88.1 (eastern Ross Sea), where fishing occurs during the austral summer from December to February, influenced by retreat. Catch limits are set annually by CCAMLR's Scientific Committee based on assessments integrating catch-per-unit-effort data, tagging returns, and models, with a precautionary approach emphasizing impacts. For the 2024/25 season, the limit for subarea 88.1 and adjacent divisions stands at 3,278 tonnes, contributing to regional harvests averaging around 4,000 tonnes annually across Ross and Amundsen Seas. Actual landings have remained below limits, with 2021 assessments estimating spawning at 62.7% of unfished levels, indicating despite historical . No commercial operates in the region, limiting activities to demersal finfish. Management mandates 100% observer coverage on authorized vessels, real-time reporting via vessel monitoring systems, and bycatch mitigation, including move-on distances exceeding 5 nautical miles when thresholds for species like skates are reached. Tagging programs require releasing at least one toothfish per tonne caught to track movements and growth, informing integrated assessments. New Zealand, a key participant, allocates quotas through its Quota Management System, with vessels required to comply with CCAMLR standards for licensing and port inspections. Post-2017 Ross Sea Region Marine Protected Area designation, fishing persists in non-protected zones, with no evidence of reduced catch rates or displaced effort, as productive grounds remain accessible. Sustainability claims rest on CCAMLR's ecosystem-based framework, though independent verification highlights ongoing needs for refined bycatch data and climate influence modeling.

Scientific Research and Infrastructure

The Ross Sea region supports extensive scientific infrastructure, primarily through coastal research stations that enable year-round and seasonal operations focused on ocean-atmosphere interactions, ice dynamics, and marine ecosystems. , the largest Antarctic facility managed by the United States National Science Foundation since 1955, is positioned on the southern tip of overlooking the Ross Sea, functioning as a central logistics hub with capacity for over 1,000 personnel during peak summer operations and supporting airfield, port, and laboratory facilities for deploying field teams across the continent. Adjacent , operated by Antarctica New Zealand, complements this infrastructure with its own runway and wharf capabilities, hosting collaborative projects involving seismic monitoring and atmospheric studies proximate to the . Additional stations include Italy's Mario Zucchelli Station on Terra Nova Bay, which reopened post-austral winter in 2023 after upgrades for enhanced access and supports multidisciplinary teams in and , as observed in . China inaugurated its Ross Sea New Station in February 2024 on Inexpressible Island, designed for up to 80 researchers with features like a constructed by January 2024, aimed at studying the region's pristine environment through oceanographic and meteorological observations. Construction on China's Station, also near the Ross Sea, advanced rapidly by December 2024, incorporating modular buildings for expanded presence in and sampling. Vessel-based infrastructure has expanded to address seasonal sea ice challenges, with deploying the RV for targeted surveys and international collaborations utilizing icebreakers like the for mooring deployments and under-ice sampling. Key projects leverage this network, such as the ROSETTA-Ice initiative (2017–ongoing), which integrates airborne , shipborne , and autonomous vehicles to map sub-ice shelf cavities and assess ocean-driven melting rates exceeding 1 meter per year in localized hotspots. The International Ocean Discovery Program's Expedition 374 (2018) cored sediments from the Ross Sea , revealing Miocene-Pliocene advances tied to and CO2 thresholds around 400 ppm, with data indicating recurrent grounding line retreats. Autonomous systems further bolster infrastructure, as in the RESTORE project deploying the unmanned underwater vehicle for real-time monitoring of dense shelf water formation and dynamics, capturing currents up to 0.5 m/s and gradients critical for global . These efforts, coordinated via networks like the Ross Sea Research Coordination Network established in the early , prioritize data integration across disciplines while navigating logistical constraints from katabatic winds exceeding 50 m/s and multi-year ice coverage averaging 60% in winter. Empirical outputs from such platforms, including paleoceanographic proxies showing past Circumpolar Deep Water intrusions warming basal ice by 1–2°C over 40,000 years, underscore the region's role in validating coupled ice-ocean models against altimetry and float observations.

Conservation and Management

Establishment of the Marine Protected Area

The Ross Sea region (RSrMPA) was first proposed in May 2012 by and the to the Commission for the Conservation of Marine Living Resources (CCAMLR), an international body established under the 1982 Convention on the Conservation of Marine Living Resources to manage fisheries and ecosystems. The initial joint proposal aimed to designate approximately 1.6 million square kilometers as protected to safeguard the region's high , including key predator-prey dynamics and pristine habitats minimally impacted by human activity. Negotiations proved protracted, spanning five annual CCAMLR meetings from to , with repeated revisions to address concerns over fishing access, scientific research provisions, and geopolitical interests; objectors including and sought exemptions for commercial toothfish fisheries and emphasized research needs over broad restrictions, leading to a reduced protected footprint and zoned allowances for limited extraction. was achieved at CCAMLR's 35th annual meeting in , , where delegates from 24 member states and the [European Union](/page/European Union) adopted Conservation Measure 91-05 on 28 October , designating the RSrMPA as the world's largest contiguous at 1.55 million square kilometers—roughly twice the size of . The measure's core objectives, as outlined in Conservation Measure 91-05, focus on conserving Antarctic marine living resources through representativeness of habitats and , of fishing threats to function, protection of critical life-history stages for long-lived like and Adélie penguins, and establishment of reference areas for monitoring climate and human impacts. The MPA divides into three zones: a General Protection Zone (1.12 million km², approximately 72% no-take to preserve trophic webs), a Special Research Zone permitting targeted fisheries for on toothfish population dynamics, and a Fisheries Research Area allowing experimental catches under strict quotas. Implementation commenced on 1 December 2017, following ratification by CCAMLR members, with a 35-year initial term subject to review and potential extension based on empirical assessments of ecological outcomes. This designation marked CCAMLR's first high-seas of such scale, prioritizing causal linkages between fishing pressure and while balancing scientific inquiry and limited resource use.

Fisheries Regulation and Economic Considerations

The fisheries of the Ross Sea region, primarily targeting (Dissostichus mawsoni), fall under the jurisdiction of the Commission for the Conservation of Antarctic Marine Living Resources (CCAMLR), which implements ecosystem-based management through conservation measures. These include total allowable catches (TACs) for Subarea 88.1, determined biennially via Bayesian sex- and age-structured stock assessment models that integrate catch data, surveys, and tagging studies to estimate sustainable yields. The , classified as exploratory since its in 1998, permits only demersal longlining, with banned to minimize seabed impacts and of non-target like skates and . All licensed vessels—limited in number by CCAMLR—must maintain 100% scientific observer coverage to report daily catches, effort, and biological data, enabling real-time adjustments and closure if limits are approached. The 2016 Ross Sea region (RSr ), enacted via CCAMLR Conservation Measure 91-05 and spanning approximately 1.55 million square kilometers, divides the region into a General Protection (banning ), a Special (for scientific purposes only), and limited areas comprising about 20% of the where regulated harvests continue. This zoned approach, agreed after protracted negotiations, preserves core habitats while allowing TACs—recently aligned with catches of 3,000–4,000 tonnes annually—to support stock stability, with assessments indicating biomass at roughly 80% of unfished levels. relies on vessel monitoring systems, port inspections, and aerial surveillance coordinated by members like , which has flagged illegal, unreported, and unregulated (IUU) vessels for CCAMLR blacklisting. IUU activity remains lower in the ice-bound Ross Sea than in less remote fisheries, attributable to seasonal inaccessibility and stringent compliance by authorized fleets. Economically, the toothfish yields high returns due to the ' premium , with wholesale prices historically around NZ$50 million for annual harvests equivalent to about 100,000 , and retail fetches up to US$17 per in destinations like the and . Catches have stabilized near TAC limits since 2009, reflecting effective quota adherence rather than depletion, though variability influences operational costs and accessibility. The sector's value to CCAMLR members—primarily New Zealand-flagged operations with international participation—is modest relative to their broader fleets, prioritizing long-term over maximization to avoid ecological collapse that could erase future revenues. Regulations thus embed economic incentives for compliance, as overfishing risks certification loss (achieved in 2010 and maintained through verified low ) and heightened IUU competition.

Debates Over Effectiveness and Geopolitical Tensions

The Ross Sea region (RSrMPA), designated by the for the of Living Resources (CCAMLR) on October 28, 2016, and entering into force on December 1, 2017, for an initial 35-year period, has faced scrutiny over its ecological efficacy due to its zoned design and enforcement limitations. Covering 1.55 million square kilometers, the includes a General Protection Zone prohibiting , a Special Research Zone permitting limited (Dissostichus mawsoni) harvesting under quotas, and a Krill Research Zone allowing (Euphausia superba) fishing for scientific purposes. Critics argue this structure compromises full protection, as the Special Research Zone sustains commercial interests—allocating up to 6,200 tonnes annually for toothfish—potentially undermining recovery in productive fishing grounds, with boundary reductions of approximately 40% during 2013 negotiations to accommodate such access. Empirical assessments indicate increased biomass in no-take areas and safeguarding for large predators, yet highly mobile like toothfish evade fixed-zone benefits, and external pressures such as climate-driven loss diminish overall outcomes. Enforcement debates center on the region's remoteness, vast scale, and reliance on vessel systems (), raising risks of non-compliance and "paper park" status without robust patrols or satellite verification. A 2021 review highlighted compliance gaps in CCAMLR's framework, exemplified by the Russian-flagged vessel Palmer, detected by patrols on January 1, 2020, allegedly fishing in prohibited Ross Sea subareas while falsifying data to report positions 800 nautical miles distant; submitted photographic evidence seeking its blacklist on the illegal, unreported, and unregulated (IUU) vessel list, but Russia's veto under CCAMLR's rule blocked action, underscoring systemic weaknesses in verifying and penalizing violations. Proponents cite coordinated , including U.S.-led programs since 2017, as evidence of yielding early ecological gains, though long-term data through 2052 remains essential to validate claims against baseline reductions from pre-MPA toothfish catches exceeding 4,000 tonnes annually. Geopolitical tensions during the RSrMPA's protracted negotiations from 2012 onward reflected clashes between conservation advocates and resource-dependent states, with the and as lead proponents compromising on initial proposals to secure consensus. The U.S. favored expansive no-take zones, while New Zealand prioritized toothfish access in the Special Research Zone to sustain its , resulting in a 2012 hybrid design; further concessions included excising northern sectors in 2013 amid scientific disputes and adding the Krill Research Zone in 2015 to address China's harvesting interests following bilateral U.S.-China . Russia withheld support until 2016, leveraging power to demand elevated toothfish quotas and citing historical sovereignty frictions with New Zealand, after earlier blocking the proposal in 2014 alongside over assertions of insufficient scientific justification and undue restrictions on legitimate fishing. These dynamics expose CCAMLR's consensus mechanism as favoring fishing nations like and , which prioritize economic yields—evident in stalled East Antarctica and MPA proposals—over precautionary conservation, potentially eroding the RSrMPA's longevity as review approaches in 2052. Incidents like the Palmer dispute amplify distrust, with decrying Russia's evasion of transparency via unpublished VMS data, while Russia insists on "neutral evidence" standards, illustrating how national interests hinder uniform enforcement and renew debates on reforming CCAMLR for binding majorities to bolster MPA integrity.

References

  1. [1]
    Ocean-atmosphere-ice processes in the Ross Sea: A review
    The Ross Sea is a vast, deep bay in the southwestern Pacific Ocean bounded by Marie Byrd Land to the east, Victoria Land to the west and the Ross Ice Shelf (RIS) ...
  2. [2]
    The Ross Sea in a Sea of Change - The Oceanography Society
    Oct 2, 2015 · The Ross Sea, the most productive region in the Antarctic, reaches farther south than any body of water in the world.Missing: exploration | Show results with:exploration
  3. [3]
    Sea ice variability and primary productivity in the Ross Sea ...
    May 23, 2009 · The Ross Sea contains the most biologically productive continental shelf in Antarctica and is a region where the annual formation of sea ice ...Missing: biodiversity | Show results with:biodiversity
  4. [4]
    ROSETTA-Ice — Ross Ice Shelf, Antarctica - USGS.gov
    May 27, 2019 · With an area of 487,000 km2, roughly the size of France, RIS ranges in thickness from 1,200 m closest to the grounding line to less than 300 m ...Missing: facts | Show results with:facts
  5. [5]
    Antarctica's Ross Sea - Blue Nature Alliance
    Its icy waters support a vibrant and highly productive ecosystem, home to several species of whales, penguins, seals, and rich benthic ecosystems packed with ...
  6. [6]
    Marine Protected Area in Antarctica's Ross Sea - NOAA Fisheries
    Apr 29, 2021 · Covering an area of 600000 square miles in the Ross Sea, the new MPA will be protected from commercial fishing for 35 years.
  7. [7]
    Ross Sea region Marine Protected Area: Antarctica Treaty System
    History. The Ross Sea region MPA was established on 1 December 2017 after years of international collaborative effort and negotiation. Jointly led by New ...
  8. [8]
    Biogeochemistry of the Ross Sea and its ecosystem implication
    It is a key site for production of Antarctic Bottom Water (AABW) and supports the largest primary productivity in the Southern Ocean. Moreover, it plays a ...Missing: biodiversity exploration
  9. [9]
    [PDF] the Ross Sea, Antarctica, Where All Ecosystem Processes Still ...
    The Ross Sea is a well-defined embayment of Antarctica about the size of southern Europe, bounded by Victoria. Land to the west, King Edward VII Peninsula ...
  10. [10]
    A recount of Ross Sea waters - ScienceDirect
    One of those regions is the Ross Sea (Fig. 1), the vast triangular-shaped region extending between Cape Adare and Cape Colbeck. Antarctic Bottom Water (AABW) ...Missing: geographical | Show results with:geographical
  11. [11]
    Exploring the Unknown of the Ross Sea in Sea Ice–Free Conditions
    Oct 11, 2018 · The southern boundary of the Ross Sea is the Ross ice shelf—Earth's largest body of floating land ice—which starts floating at the grounding ...
  12. [12]
    Ross Sea Region projections | Geodetic Guidance
    Apr 5, 2024 · The Ross Sea Region covers the sector of Antarctica between 160° East, 150° West and 60° South. The Ross Sea Region Geodetic Datum 2000 ( ...
  13. [13]
    Ross Sea Benthic Ecosystems: Macro- and Mega-faunal Community ...
    The influence of productivity on benthic biomass and abundance in food limited Antarctic ecosystems has been repeatedly demonstrated (e.g., Brey and Clarke, ...
  14. [14]
    [PDF] The Ross Sea: In a Sea of Change | ODU Digital Commons
    Summary of features of the ross Sea continental shelf based on the bathymetry used in orsi and Wiederwohl (2009), where the ross Sea continental shelf is ...
  15. [15]
    [PDF] a new account of ross sea waters: characteristics - Southern Ocean
    A conspicuous characteristic of the Ross sea continental shelves is the rugged seafloor topography, which on average is about 685 m deep. There are several ...
  16. [16]
    [PDF] 34. a geophysical study of the ross sea, antarctica1
    Bathymetric contour map of the western Ross. Sea rise. Depths are in meters. The positions of two sub- marine channels are shown by the line of arrowheads.Missing: width | Show results with:width
  17. [17]
    [PDF] retreat scenarios and changing controls in the Ross Sea, Antarctica
    May 13, 2016 · The Central Basin is a bathymetric low that reaches wa- ter depths of over 1000m, situated south of all three WRS troughs. It contains multiple ...<|separator|>
  18. [18]
    [PDF] The Oceanography and Ecology of the Ross Sea
    Aug 21, 2013 · Because of the low stratification over the continental shelf, the circulation on much of the shelf is strongly forced by the bathymetry owing ...
  19. [19]
    Bathymetry of the Antarctic continental shelf and ice shelf cavities ...
    Jan 7, 2025 · We present a novel and comprehensive bathymetry of Antarctica that includes all ice shelf cavities and previously unmeasured continental shelf areas.
  20. [20]
    Antarctic Explorers: James Clark Ross - South-Pole.com
    At 5 am on January 9 they broke into an open sea. Ross had discovered the Ross Sea and he now set his sights on the south magnetic pole. On January 11 land ...
  21. [21]
    13 James Clark Ross (1839-43) - Antarctic Guide
    He pushed south, sometimes through heavy ice, to break into open sea on 9 January. He had discovered the Ross Sea, the best ocean access to the South Geographic ...Missing: facts | Show results with:facts
  22. [22]
    History of Antarctic explorers | Royal Museums Greenwich
    During the expedition, Ross discovers the Ross Sea and Ross Ice Shelf: this region would later serve as the starting point for both Amundsen and Scott's ...Missing: primary | Show results with:primary
  23. [23]
    British Antarctic Expedition [I] (1839 - 1843)
    Other major achievements included the discovery of the Ross Sea and its ice shelf, and Victorian Land; charting c. 500 miles of coast in this region; the ...Missing: itinerary | Show results with:itinerary<|separator|>
  24. [24]
    South Pole exploration: Robert Falcon Scott, 1901–04
    Robert Falcon Scott led the first British expedition that attempted to reach it. Scott's first expedition, 1901–04. Scott was born on 6 June 1868 near ...Missing: Sea | Show results with:Sea
  25. [25]
    Scott's Hut - Hut Point - Antarctic Heritage Trust
    Established in February 1902, this base is associated with Commander Robert Falcon Scott's National Antarctic (Discovery) Expedition 1901–1904. ... Ross Sea Party ...
  26. [26]
    Shackleton's Hut - Antarctic Heritage Trust
    The Nimrod expedition was the third British expedition to the Ross Sea region within 10 years. Travelling with Shackleton on the 200 ton Nimrod, were a ...
  27. [27]
    Ernest Shackleton's Nimrod Expedition
    Aug 8, 2021 · Despite severe problems, Nimrod landed at Cape Royds, Ross Island, in early 1908 to start preparations for the assault on the Pole the following ...
  28. [28]
    HSM 15: Shackleton's 'Nimrod' Hut - Cape Royds, Ross Island
    Hut at Cape Royds, Ross Island, built in February 1908 by the British Antarctic Expedition of 1907-09, led by Sir Ernest Shackleton.<|control11|><|separator|>
  29. [29]
    History of Scott's Expedition - Antarctic Heritage Trust
    Arriving at Ross Island in January 1911, a landing was made at Cape Crozier but the idea of setting up the base here was abandoned. Thick sea-ice prevented the ...
  30. [30]
    Roald Amundsen's Legendary South Pole Expedition
    It was British explorer Robert Falcon Scott and Norwegian explorer Roald Amundsen who went head to head with each other in a race to the Pole in 1911.
  31. [31]
    The Tragic Story of Shackleton's Stranded Ross Sea Party - History Hit
    As his Endurance sank in the Weddell Sea in late 1915, Shackleton restated his determination that he would lose no man under his command.
  32. [32]
    Polar Exploration - Naval History and Heritage Command
    Dec 19, 2024 · The US Navy has a long history in polar exploration. As early as 1839, Captain Charles Wilkes led the first US naval expedition into Antarctic waters.Missing: post- | Show results with:post-
  33. [33]
    United States Navy Antarctic Expeditions Operation Deep Freeze ...
    The primary mission of the 1955-56 operation was to establish two stations along the Ross Sea and the transportation of personnel, equipment, and supplies ...
  34. [34]
    International Geophysical Year (IGY) - Antarctic Heritage Trust
    Aug 4, 2020 · Between 1957 and 1958, the New Zealanders carried out research into 11 fields of science. Through seismic and geodetic surveying carried out ...
  35. [35]
    [PDF] U.S. Geological Survey Scientific Activities in the Exploration of ...
    May 2, 2007 · Geologic studies were carried out at coastal sites in the Ross Sea (future site of Little America V; McMurdo. Station), Edward VII Peninsula, ...
  36. [36]
    [PDF] OPERATION DEEP FREEZE 62, 1961-1962 MARINE ... - DTIC
    The lateral and vertical extent of this warm-water penetraticn Into the Ross Sea during the Austral summer Is described. Measuremnents of the earthnls total m ...
  37. [37]
    Surveying in the Ross Sea | Hydro International
    May 9, 2007 · Planning is also under way for Tangaroa to return to Antarctica in February–March 2008 as part of an International Polar Year (IPY) initiative.Missing: modern | Show results with:modern
  38. [38]
    The International Bathymetric Chart of the Southern Ocean Version 2
    Jun 7, 2022 · IBCSO v2 significantly improves the overall representation of the Southern Ocean seafloor and resolves many submarine landforms in more detail.
  39. [39]
    Seasonal variations in Circumpolar Deep Water intrusions into the ...
    Mar 9, 2023 · The broad Ross Sea continental shelf covers over 4.6 × 105 km2, and the shelf break occurs at the 700-m isobath (Budillon et al., 2006; Smith ...Introduction · Materials and methods · Results · Discussions
  40. [40]
    Till Sheets on the Ross Sea Continental Shelf, Antarctica
    Ross Sea is a broad embayment, approximately 1500 km wide and 900 km long, on the Antarctic coast (Fig. 1). Water depths range from less than 300 m to ...Missing: width | Show results with:width
  41. [41]
    The Eastern Ross Sea continental shelf during the Cenozoic
    (1) Pre-Miocene: the Eastern Ross Sea was a deep structural basin bordered to the west by areas (e.g., the Central High) outcropping the sea level and hosting ...
  42. [42]
    Basement Topography and Sediment Thickness Beneath ...
    May 9, 2022 · Flanking the high are wide sedimentary basins, up to 3700m deep, which parallel the Ross Sea basins and likely formed during Cretaceous-Neogene ...
  43. [43]
    [PDF] volcanic geology of mount erebus, ross island, antarctica
    The basement of the Ross Sea, 4-5 km below sea level. (McGINNIS et al., 1983), consists of granitic, metamorphic and sedimentary rocks similar to those exposed ...
  44. [44]
    3-D density structure of the Ross Sea basins, West Antarctica from ...
    This paper reports new information on the 3-D density structure of the Ross Sea obtained using gravity inversion performed with the GRAV3D algorithm and other ...
  45. [45]
    Bathymetry and geological structures beneath the Ross Ice Shelf at ...
    Aug 3, 2013 · A sediment-filled graben approximately 2500 m deep and 20 km wide has also been imaged by a combined seismic-refraction and gravity survey near ...
  46. [46]
    Sedimentary basins of the Ross Sea, Antarctica
    This basin is considered to have formed partially in response to loading by glacial sediments since the Oligocene. A major trough of sediments, also up to 4 km ...Missing: stratigraphy | Show results with:stratigraphy
  47. [47]
    Seismic stratigraphy of the Central Basin in northwestern Ross Sea ...
    The sedimentary successions above the acoustic basement were divided into eight seismic sequences, termed Ross Sea Seismic Sequences (RSS-1 to RSS-8), with ...
  48. [48]
    Early and middle Miocene ice sheet dynamics in the Ross Sea
    May 11, 2021 · In the western Ross Sea, Pennell, Joides, and Drygalski basins are separated by Pennell and Crary-Mawson banks, which are composed of ...
  49. [49]
    Miocene ice sheet dynamics and sediment deposition in the central ...
    Oct 9, 2024 · Here, we provide a sedimentary facies analysis of drill cores from International Ocean Discovery Program (IODP) Site U1521 in the Ross Sea, ...
  50. [50]
    Chronology and Sedimentary Processes in the Western Ross Sea ...
    Jan 31, 2024 · The Ross Sea is the second largest bay in the Southern Ocean (72–77° S, 160° E–160° W), and studies on sediments in this key region have ...
  51. [51]
    [PDF] Sediment accumulation rates from the Ross Sea continental shelf ...
    In low latitude basins, the sequence stratigraphic paradigm indicates the highest rates of sediment accumulation occur during rapid relative sea level fall ( ...
  52. [52]
    Geochronology and Paleoenvironmental Changes of Late ... - Frontiers
    Overall, the sedimentary record in the Ross Sea documents some key features of the paleoenvironmental processes in the Late Pleistocene, which could be ...<|separator|>
  53. [53]
    Petrographic signature of the gravel fraction from late Quaternary ...
    Western Ross Sea cores are characterized by a distinct, although variable, clast assemblage. Indeed, in 3 out of 9 cores (i.e. 80-189; 78-09; 94-16), volcanic ...
  54. [54]
    Grain-size, coarse fraction lithology and clay mineral compositions ...
    Jan 10, 2024 · These clay minerals primarily originate from the Ross Sea Embayment itself through a binary mixing process. Illite and chlorite ...
  55. [55]
    Spatial and historical patterns of sedimentary organic matter sources ...
    Oct 6, 2024 · The overall sorting of surface sediments in the Ross Sea was poor, indicating a low-energy and hydrodynamically stable sedimentary environment.
  56. [56]
    New results from the ANDRILL McMurdo Ice Shelf Project
    The ANtarctic DRILLing (ANDRILL) Program's recently recovered AND-1B drill core provides a 1285-m-thick Late Neogene (last 14 Ma) record from beneath the ...Missing: SMS | Show results with:SMS
  57. [57]
    Heat Flow and Hydrologic Characteristics at the AND-1B borehole ...
    Aug 1, 2010 · The Antarctic Drilling Program (ANDRILL) successfully drilled and cored a borehole, AND-1B, beneath the McMurdo Ice Shelf and into a ...
  58. [58]
    The ANDRILL drilling project - 1284.87 m and 1138.54 m sediment ...
    The goal of ANDRILL was to gain an understanding of the past behaviour of the Antarctic Ice Sheets (east and west) and the McMurdo/Ross Ice Shelf and their role ...
  59. [59]
    New Paleoclimate Insights From Southern Ocean and Antarctic ...
    Oct 2, 2015 · Early-Middle Miocene (17–14 Ma) Antarctic ice dynamics reconstructed from the heavy mineral provenance in the AND-2A drill core, Ross Sea, ...
  60. [60]
    The upper lithostratigraphic unit of ANDRILL AND-2A core ...
    We report results from the study of the uppermost 37 m of the Southern McMurdo Sound (SMS) AND-2A drill core, corresponding to the lithostratigraphic unit 1 ...
  61. [61]
    Expedition 374 summary - IODP Publications
    Aug 10, 2019 · Two ANDRILL sites drilled on the inner continental shelf of the western Ross Sea ... Sea Drilling Project Site 270, Ross Sea, Antarctica. In ...<|separator|>
  62. [62]
    Volume 374 expedition reports • Site U1524 - IODP Publications
    Aug 10, 2019 · The levee at this site has a relief of ~500 m and is located ~120 km north of the Ross Sea continental shelf edge. The head of the Hillary ...
  63. [63]
    Andrill - United States Antarctic Program Data Center (USAP-DC)
    Harry, Dennis L. Geodynamic Models of Subsidence and Lithospheric Flexure at the ANDRILL Drill Sites: Implications for Cenozoic Tectonics and Ice Sheet History
  64. [64]
    A sedimentological record of early Miocene ice advance and retreat ...
    Jun 8, 2018 · INTRODUCTION. The Antarctic Geological Drilling Program (ANDRILL) aimed to provide proximal records of Antarctic Cenozoic ice sheet advance and ...
  65. [65]
    The Density‐Driven Winter Intensification of the Ross Sea Circulation
    Oct 2, 2018 · A system of two cyclonic and three anticyclonic persistent circulation features has been identified. Transports steadily increase throughout ...2.2 Wind Stress Sensitivity... · 3.3 Hssw--Formation And... · 3.4 Ice Shelf Melting And...
  66. [66]
    Evidence for large-scale climate forcing of dense shelf water ...
    Sep 18, 2024 · We show that significant correlation exists between interannual variability of DSW production in the Ross Sea polynyas, where DSW contributes between 20–40% of ...
  67. [67]
    Antarctic Bottom Water and the Ross Sea
    Figure 1: Winds and ocean currents create polynyas, areas of open water surrounded by ice, exposing the surface to freezing temperatures. Integrated and ...
  68. [68]
    The response of sea ice and high-salinity shelf water in the Ross Ice ...
    Mar 6, 2023 · This study reveals the impacts of cyclones on sea ice and water mass formation in the Ross Ice Shelf Polynya using numerical simulations. Sea ...<|separator|>
  69. [69]
    [PDF] Frazil ice growth and production during katabatic wind events in ... - TC
    Oct 30, 2019 · In the case of the Ross Sea, the cold, dense HSSW formed on the shelf eventually becomes AABW off the shelf, the densest water in global ...
  70. [70]
    Substantial Contraction of Dense Shelf Water in the Ross Sea Under ...
    Mar 10, 2025 · Brine released during sea ice formation in polynyas increases the salinity of surface waters, resulting in deep ocean convection and ultimately ...
  71. [71]
    The Ross Sea and Amundsen Sea Ice–Sea Model (RAISE v1.0)
    Mar 5, 2025 · Brine rejection during ice formation further drives deep-ocean convection, leading to the formation of the Dense Shelf Water (DSW) in the ...
  72. [72]
    A Model‐Based Investigation of the Recent Rebound of Shelf Water ...
    Sep 16, 2024 · Oceanic processes and salinity relaxation counteract the salinity tendency implied by sea ice brine rejection. ... Ross Sea polynya near the coast ...
  73. [73]
    An 83 000-year-old ice core from Roosevelt Island, Ross Sea ... - CP
    Sep 2, 2020 · In 2013 an ice core was recovered from Roosevelt Island, an ice dome between two submarine troughs carved by paleo-ice-streams in the Ross Sea, Antarctica.
  74. [74]
    Past intrusion of Circumpolar Deep Water in the Ross Sea - Science
    Jun 27, 2025 · Our data show that warm Circumpolar Deep Water reached the JOIDES Trough in the western Ross Sea shortly after the Last Glacial Maximum.
  75. [75]
    Holocene paleoceanographic variability in Robertson Bay, Ross ...
    May 15, 2024 · Increasing mass loss from the WAIS has freshened surface waters in the Ross Sea since the 1950s (Jacobs et al., 2022), and freshened surface ...Missing: surveys | Show results with:surveys
  76. [76]
    Widespread collapse of the Ross Ice Shelf during the late Holocene
    Thus, ice-shelf retreat in the Ross Sea is consistent with ice-core records of atmospheric warming in the region. Timing of ice-shelf retreat observed here ...<|separator|>
  77. [77]
    temperature, snow accumulation and sea ice variability in the Ross ...
    Notably, during the Little Ice Age, West Antarctica and the western Ross Sea experienced colder than average temperatures, while the eastern Ross Sea underwent ...
  78. [78]
    [PDF] A 1400-Year Oxygen Isotope History from the Ross Sea Area ...
    Four ice cores from the Ross Sea drainage, Antarctica, show patterns of 5180 variations on a time scale of decades to centuries over the last 1400 years ...
  79. [79]
    Pleistocene oceanographic variability in the Ross Sea: A multiproxy ...
    This study investigates the 11.75 m sediment core RS15-LC42, retrieved from the Central Basin of the Ross Sea.
  80. [80]
    Increase of the Antarctic Sea Ice Extent is highly significant only in ...
    Jan 24, 2017 · Only the SIE over Ross Sea has experienced a highly significant increasing trend (p = 0.008) which cannot be explained by natural variability.
  81. [81]
    Changing Antarctic Sea Ice
    Antarctic sea ice is gradually increasing for a number of reasons, including changes in winds, increased ocean stratification and increased freshwater flux ...
  82. [82]
    Antarctic sea ice maximum settles in third place
    On September 17, 2025, Antarctic sea ice extent likely peaked with a maximum of 17.81 million square kilometers (6.88 million square miles), the third lowest ...Missing: 2000-2025 | Show results with:2000-2025
  83. [83]
    Persistent Ross Sea Freshening From Imbalance West Antarctic Ice ...
    Feb 28, 2022 · Seawater properties on the Ross CS are influenced by sea ice formation and melting, changes in the atmosphere and ocean circulations, ...
  84. [84]
    Ross Ice Shelf frontal zone subjected to increasing melting by ocean ...
    Nov 8, 2024 · The heat advected beneath the Ross Ice Shelf by surface water, observed here directly, has increased over the past 40 years. INTRODUCTION. The ...
  85. [85]
    [PDF] The changing extent of the glaciers along the western Ross Sea ...
    We examine the change in terminus positions of glaciers flowing into the western Ross Sea, Antarctica, between 71°S and 78°S as a proxy for changes in snowfall ...
  86. [86]
    Holes in Ross Sea Ice Grow and Shrink in Unexpected Cycle - Eos.org
    Apr 9, 2024 · A team analyzing those data unexpectedly found that in the Ross Sea region, the area of polynyas appears to fluctuate on a 16-year cycle.
  87. [87]
    Projected Changes to the Southern Hemisphere Ocean and Sea Ice ...
    A robust decrease is projected for both the sea ice concentration and the seasonal cycling of ice volume, potentially altering the salt and heat budget at high ...
  88. [88]
    Effects of Projected Changes in Wind, Atmospheric Temperature ...
    A 5-km horizontal resolution regional ocean–sea ice–ice shelf model of the Ross Sea is used to examine the effects of changes in wind strength, air temperature ...
  89. [89]
    [PDF] Global Climate Projections
    on the long-term future of the ice sheet or its contribution to sea level ... the Ross Sea where most models predict a local minimum in surface warming ...
  90. [90]
    Projections of winter polynyas and their biophysical impacts in the ...
    Sep 23, 2023 · We focus on the wind forcing in the Ross Sea because the Ross Sea Polynya is forced by southerly winds coming off the Antarctic continent. The ...
  91. [91]
    Future changes in Antarctic coastal polynyas and bottom water ...
    Dec 20, 2023 · Here, we investigate the future evolution of Antarctic coastal polynyas using a high-resolution ocean-ice-atmosphere model.Results · Antarctic Sea Ice Production · Surface Heat Fluxes
  92. [92]
    [PDF] CCAMLR - Antarctic and Southern Ocean Coalition
    The Ross Sea possesses a high level of habitat diversity due to its physical characteristics, namely a “shallow shelf with deep troughs bordering shallow banks, ...
  93. [93]
    Research - Project 3: Ecosystems - Antarctic Science Platform
    The Ross Sea region contains one of the most productive marine ecosystems in the Southern Ocean, encompassing open ocean, pack ice, and coastal habitats.
  94. [94]
    [PDF] Antarctic Ocean Legacy a marine reserve for the Ross Sea
    The biodiversity of the Ross Sea begins with its unusually high production of phytoplankton (microscopic plant plankton), estimated to be 28% of the total ...
  95. [95]
    Week 8: Food web of the Ross Sea - Science Learning Hub
    Tiny plants called phytoplankton are found floating in the water or frozen in sea ice. They get eaten by herbivores such as krill and zooplankton. Carnivores in ...
  96. [96]
    Interactions between krill and its predators in the western Ross Sea
    Mar 6, 2024 · Krill is a fundamental resource in the pelagic food web of the Ross Sea, constituting an important link between primary production and top predators.
  97. [97]
    Trophic interactions within the Ross Sea continental shelf ecosystem
    Similarly, we suggest that benthic–pelagic coupling is stronger in the Ross Sea than in most other Antarctic regions. We also highlight many of the unknowns ...
  98. [98]
    Oceanographic Versus Seafloor‐Habitat Control of Benthic ...
    Jan 3, 2003 · Benthic megafaunal assemblages between 270 and 1173 m depth in the SW Ross Sea were characterized from analyses of fifty-five seafloor video transects.<|separator|>
  99. [99]
    [PDF] Sea Ice Biota: Trophic modelling of the Ross Sea - CCAMLR
    The microhabitats include: (1) ponds on the upper surface of the ice; (2) slush or snow on the top of the sea ice; (3) between different layers within the ...
  100. [100]
    [PDF] THE CASE FOR A MARINE RESERVE IN THE ROSS SEA
    The biodiversity in the region includes a significant percentage of the global distributions of Adélie penguins. (38 percent), emperor penguins (26 percent),.
  101. [101]
    The Ross Sea region as a model system - Conservation Biology
    Sep 19, 2024 · The Ross Sea is one of the most productive regions in the Southern Ocean, supporting a disproportionate abundance of flora and fauna for its ...Missing: types | Show results with:types
  102. [102]
    Investigating Whales Penguins and Seals on the Bottom of the World
    Jun 22, 2021 · Throughout the study, krill abundance declined in surface waters as predation by penguins and whales increased at the ice edge. Instead, krill ...
  103. [103]
    [PDF] Trophic cascades in the western Ross Sea
    We propose that the Ross Sea food web has a “wasp-waist” structure that ultimately could explain the large carbon sequestration capability of the. Ross Sea.
  104. [104]
    Trophic cascades in the western Ross Sea, Antarctica
    Hence, on one hand, diatom production may lead to a 4-level trophic chain composed of primary, secondary and tertiary consumers (diatoms−krill− fish− penguins).
  105. [105]
    [PDF] A BALANCED MODEL OF THE FOOD WEB OF THE ROSS SEA ...
    It appears, however, that benthic invertebrates are a minor but significant component of the Ross Sea food web. ... Trophic interactions within the Ross Sea.
  106. [106]
    Response of indicator species to changes in food web and ocean ...
    Species and relationships involved in the intraguild (IG) predation of Antarctic silverfish that characterize the water column food web of the Ross Sea (see ...
  107. [107]
    [PDF] Network characterisation of the food web of the Ross Sea Antarctica
    Jun 18, 2012 · The six groups with the highest 'indices of ecological importance' in the food-web of the Ross Sea are phytoplankton, mesozooplankton,.<|control11|><|separator|>
  108. [108]
    [PDF] Schedule of Conservation measures in Force 2024/25 - CCAMLR
    The schedule includes measures like vessel marking, licensing, port inspections, VMS, catch documentation, and transhipment notification.
  109. [109]
    The Ross Sea toothfish fishery | New Zealand Geographic
    It is estimated that the initial Ross Sea Antarctic toothfish spawning stock stood at 69,000 t, and that the current stock stands at 61,000 t—the equivalent of ...Missing: 2020-2025 | Show results with:2020-2025
  110. [110]
    Characterisation of the toothfish fishery in the Ross Sea region ...
    The number of Antarctic toothfish recaptured in 2020–21 was higher than the average annual number over the past decade, likely a consequence of the ...
  111. [111]
    Statistical Bulletin - CCAMLR
    May 29, 2025 · The bulletin includes catch and effort statistics, catch histories, trade statistics for toothfish, and planimetric seabed areas.Missing: Ross Sea 88.1 2020<|separator|>
  112. [112]
    [PDF] Annex 7 Report of the Working Group on Fish Stock Assessment ...
    4.105 The Working Group recommended that the catch limit for the Ross Sea region (Subarea. 88.1 and SSRUs 882A–B) be set at 3 278 tonnes for the 2024/25 and ...
  113. [113]
    Tropical teleconnections through the Amundsen Sea Low impact ...
    Nov 4, 2024 · Fishing vessels harvest about 4000 tonnes of Antarctic toothfish per year, predominantly in the Ross Sea and Amundsen Sea regions. Antarctic ...Results · Discussion And Conclusion · MethodsMissing: statistics | Show results with:statistics<|separator|>
  114. [114]
    Evaluating the impacts of the Ross Sea region marine protected ...
    Mar 1, 2024 · Our results indicate that access to productive fishing grounds continues to exist with the RSrMPA, the total catch limit and fishery catch rates ...
  115. [115]
    The Ross Sea, Antarctica: A highly protected MPA in international ...
    As the first large-scale (>150,000 km2) marine protected area (MPA) on the high seas, the Ross Sea region MPA sets a precedent for other MPAs in areas beyond ...
  116. [116]
    Fishing in the Ross Sea - Fisheries New Zealand
    Only fishing vessels authorised by CCAMLR are permitted to operate in the Ross Sea toothfish fishery. Authorised fishing vessels are required to: Carry two ...Missing: regulations | Show results with:regulations
  117. [117]
    [PDF] Commercial Data Collection Manual Longline Fisheries Version 2025
    Sep 29, 2022 · The Commission for the Conservation of Antarctic Marine Living resources (CCAMLR) requires both catch and effort reporting (CE), ...
  118. [118]
    [PDF] The Ross Sea fishery - Frequently Asked Questions (FAQ)
    All fishing vessels approved by CCAMLR and operating in the Ross sea fishery must tag and release at least one toothfish per tonne of fish caught. CCAMLR ...Missing: regulations | Show results with:regulations
  119. [119]
    [PDF] TOOTHFISH (TOT) – May 2025 - Fisheries New Zealand
    This working group report is a summary of the Ross Sea and Amundsen Sea toothfish fisheries in. CCAMLR (Statistical Subareas 88.1 and 88.2) and includes ...
  120. [120]
    The toothfish fishery | Earth Sciences New Zealand - NIWA
    The relative trend in standardised catch rate (black dots, scaled to have a mean of one) for each area in the Ross Sea fishery shows no change with time. Blue ...The Toothfish Fishery · Sea Ice Influences On The... · Ross Sea Mean Sea Ice...Missing: 2020-2025 | Show results with:2020-2025
  121. [121]
    NSF McMurdo Station - Office of Polar Programs (GEO/OPP)
    McMurdo Station, the largest scientific research station in Antarctica, is managed by the National Science Foundation. It is located next to the Ross Sea and ...
  122. [122]
    Case study: Scaling up vessel-based research in the Ross Sea
    Sep 26, 2024 · New Zealand's national polar research vessel infrastructure has traditionally been limited to the RV Tangaroa, which over recent times has ...
  123. [123]
    The Ross Sea in Antarctica | Copernicus
    Numerous scientific research stations are located along its coasts. The Zucchelli Station, which will reopen soon after the austral winter, is visible in ...
  124. [124]
    China opens Antarctic station south of Australia, New Zealand
    Feb 7, 2024 · China on Wednesday inaugurated its Ross Sea scientific research station, the official Xinhua news agency reported, starting operations in an outpost in a part ...<|separator|>
  125. [125]
    China starts building helipad at fifth Antarctica station
    Feb 1, 2024 · China started building a helipad at its fifth Antarctic scientific research station that is located on the coast of the Ross Sea on January 31.<|separator|>
  126. [126]
    China Makes Progress on Its Fifth Antarctic Research Station - CSIS
    Dec 19, 2024 · Recent satellite imagery shows construction progressing quickly at Qinling Station, located on Inexpressible Island near the Ross Sea.
  127. [127]
    ROSETTA-Ice - Polar Geophysics Group
    It is the goal of the ROSETTA-Ice Project to further our understanding of the ice, the ocean, and the underlying bed, by bringing together a multi-disciplinary ...Missing: key | Show results with:key
  128. [128]
    Proc. IODP, Expedition 374, Ross Sea West Antarctic Ice Sheet History
    Aug 10, 2019 · Using sedimentology and geochemistry to elucidate Antarctic Ice Sheet extent in the late Miocene to Pliocene: results from IODP Site U1522 on ...
  129. [129]
    Robotic-based invESTigation and mOnitoring of Ross sEa with the ...
    Research paper. Robotic-based invESTigation and mOnitoring of Ross sEa with the PROTEUS unmanned marine vehicle - The RESTORE project.
  130. [130]
    Ross Sea Research Coordination Network
    This site provides information about ongoing efforts to develop a Research Coordination Network (RCN) with the overarching goal of establishing a collaborative ...
  131. [131]
    Marine Protected Areas (MPAs) - CCAMLR
    Jul 3, 2020 · An MPA in the Ross Sea was originally proposed by both the USA and New Zealand in 2012. These proposals were later revised as a joint proposal ...
  132. [132]
    [PDF] ccamlr-xxxi - State.gov
    Sep 7, 2012 · States now proposes the establishment of the Ross Sea Region Marine Protected Area. The Ross. Sea Region is among the best studied areas of ...
  133. [133]
    The case of the Ross Sea, Antarctica - Conservation Biology - Wiley
    Sep 20, 2019 · Thus, the only activity banned in the Ross Sea MPA is industrial fishing and related activities (e.g., transshipment). CCAMLR does not have ...<|control11|><|separator|>
  134. [134]
    Designation of the Ross Sea Region Marine Protected Area - state.gov
    Dec 1, 2017 · It is 1.55 million square kilometers in size, about twice the size of the State of Texas. For further information, contact OES-PA-DG@state.gov.Missing: km2 | Show results with:km2
  135. [135]
    World's largest marine protected area declared in Antarctica - BBC
    Oct 28, 2016 · Delegates from 24 countries and the European Union have agreed that the Ross Sea in Antarctica will become the world's largest marine protected area (MPA).
  136. [136]
    [PDF] Conservation Measure 91-05 (2016) Ross Sea region marine ...
    establish an MPA in the Ross Sea region for the purpose of achieving the conservation of. Antarctic marine living resources, where conservation includes ...
  137. [137]
    Ross Sea Region MPA - Antarctic and Southern Ocean Coalition
    The Ross Sea Region MPA covers a surface area of 600,000 square miles (1.55 million square kilometers), more than three times the size of California. This does ...Missing: extent boundaries
  138. [138]
    [PDF] Ross-Sea-MPA-RMP-xxxvi-20.pdf
    Sep 1, 2017 · 2. The specific objectives for the RSRMPA fall into three main categories: representativeness, threat mitigation and scientific reference areas ...
  139. [139]
    [PDF] Stock Assessment Report 2022: Dissostichus mawsoni in Subarea ...
    Mar 14, 2023 · This paper reports on the update of the Bayesian sex- and age-structured integrated stock assessment model for Antarctic toothfish (Dissostichus ...
  140. [140]
    Commission on the Conservation of Antarctic Marine Living Resources
    CCAMLR requires 100% scientific observer coverage in all fisheries. CCAMLR adopted measures to protect vulnerable marine ecosystems (VMEs) in 2007. It has also ...
  141. [141]
    Ross Sea toothfish longline - MSC Fisheries
    Stock assessments are carried out annually and current assessments estimate the stock levels at approximately 80% of the original biomass. The fishery has ...Missing: value | Show results with:value<|separator|>
  142. [142]
    [PDF] Toothfish Fact Sheet
    Jun 15, 2023 · Traditionally, IUU fishing has not been major concern in the Ross Sea because of its remote location and ice cover for nine months of the year.
  143. [143]
    Tropical climatic phenomenon affects Antarctic fishery | Polar Journal
    Nov 14, 2024 · The Antarctic toothfish, known to live for over 50 years, spawns north of the Ross Sea. “This happens between July and October, in winter ...
  144. [144]
    [PDF] An economic analysis of the Ross Sea and East Antarctic MPA ...
    This paper is presented for consideration by CCAMLR and may contain unpublished data, analyses, and/or conclusions subject to change.<|separator|>
  145. [145]
    Ross Sea toothfish longline fishery gains MSC certification
    Dec 17, 2010 · All fishing activity is overseen by the Commission for the Conservation of Antarctic Marine Living Resources (CCAMLR) and all vessels operating ...
  146. [146]
    Marine Protected Areas: How effective are they at ... - Routes
    May 24, 2025 · This essay will consider a number of case studies in order to assess the general effectiveness of Marine Protected Areas. The Ross Sea MPA ...
  147. [147]
    Antarctic Geopolitics and the Ross Sea Marine Protected Area
    Feb 20, 2018 · The world's largest marine protected area (MPA) in the Ross Sea, Antarctica entered into force. The MPA will be in force for at least 35 years.
  148. [148]
    Controversy over Russian vessel in Antarctica reveals CCAMLR ...
    Jan 12, 2021 · A daggers-drawn dispute between New Zealand and Russia over alleged overfishing by a Russian-flagged vessel seized the spotlight.