Ice movement and distribution in the Bering Sea from March to June 1974

Muench, Robin D.; Ahlnäs, Kristina

doi:10.1029/jc081i024p04467

Cited by 56 publications

(28 citation statements)

References 3 publications

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“…Complementary information on attendant ice, weather, and oceanographic conditions was derived principally from publications by the U.S. Navy (1946Navy ( , 1956Navy ( , 1958, Webster (1954), Schule and Wittman (1958), Zenkevich (1963), Hood and Kelley (1974), Burns (1975a, 1975b), Muench and Ahlnas (1976), and Brower et al (1977), as well as from my field observations and interpretations of satellite imagery and those, especially, of J. J. Burns and L. H. Shapiro.…”

Section: Distribution and Migrationsmentioning

confidence: 99%

Ecology and Biology of the Pacific Walrus,Odobenus rosmarus divergensIlliger

Fay¹

1982

North American Fauna

394

567

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Section: Distribution and Migrationsmentioning

confidence: 99%

Ecology and Biology of the Pacific Walrus,Odobenus rosmarus divergensIlliger

Fay¹

1982

North American Fauna

394

567

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Section: Discussionmentioning

confidence: 99%

“…Regions of relatively homogeneous ice habitats are formed each year in the Bering Sea from regionally specific winds, currents, and land configurations (Muench & Ahlnas 1976, Burns et al 1980, 1981. St. Lawrence Island is a major land form affecting movements of ice in the northern Bering Sea.…”

Section: The Pacific Walrus (Odobenus Rosmarus Divergens)mentioning

confidence: 99%

“…Although the net transport of ice is southward during winter and early spring, the rate and direction of drift are not uniform throughout the pack ice (Burns et al 1981). Short-term (several days), small-scale fluctuations in ice drift occur, probably from variations in local winds, currents, and ice interactions (Muench & Ahlnas 1976).Ice over the continental shelf affords walruses the ability to exploit benthic prey over large areas. It has been recognized that when walruses rest on moving ice they can be transported to new feeding areas (Fay 1982).…”

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confidence: 99%

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Divergent movements of walrus and sea ice in the northern Bering Sea

Jay

Udevitz²,

Kwok³

et al. 2010

Mar. Ecol. Prog. Ser.

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The Pacific walrus Odobenus rosmarus divergens is a large Arctic pinniped of the Chukchi and Bering Seas. Reductions of sea ice projected to occur in the Arctic by mid-century raise concerns for conservation of the Pacific walrus. To understand the significance of sea ice loss to the viability of walruses, it would be useful to better understand the spatial associations between the movements of sea ice and walruses. We investigated whether local-scale (~1 to 100 km) walrus movements correspond to movements of sea ice in the Bering Sea in early spring, using locations from radio-tracked walruses and measures of ice floe movements from processed synthetic aperture radar satellite imagery. We used generalized linear mixed-effects models to analyze the angle between walrus and ice floe movement vectors and the distance between the final geographic position of walruses and their associated ice floes (displacement), as functions of observation duration, proportion of time the walrus was in water, and geographic region. Analyses were based on 121 walrus-ice vector pairs and observations lasting 12 to 36 h. Angles and displacements increased with observation duration, proportion of time the walrus spent in the water, and varied among regions (regional mean angles ranged from 40°to 81°and mean displacements ranged from 15 to 35 km). Our results indicated a lack of correspondence between walruses and their initially associated ice floes, suggesting that local areas of walrus activities were independent of the movement of ice floes. KEY WORDS: Pacific walrus · Odobenus rosmarus · Bering Sea · Sea ice · Telemetry · RADARSAT · RGPS · SAR Resale or republication not permitted without written consent of the publisherMar Ecol Prog Ser 407: [293][294][295][296][297][298][299][300][301][302] 2010 Seasonal movements of sea ice over the Chukchi and Bering Seas allow walruses to occupy a wide area over the continental shelf during the year. Walruses typically occur in areas of unconsolidated ice, open leads, and thin ice where they can create breathing holes (Burns et al. 1980, 1981, Fay 1982. In winter, the entire Pacific walrus population resides in the Bering Sea, and it is here on the sea ice that breeding courtships (January to February) and most of the calving (April to June) occur. Most adult female and young walruses prefer to use sea ice for hauling out throughout the year. In spring, they follow the receding ice pack northward to summer in the Chukchi Sea. Unlike females, most adult male walruses summer near coastal areas of the Bering Sea, using land haul-outs to rest between foraging trips. In autumn, the female and young walruses in the Chukchi Sea migrate with the developing sea ice southward into the Bering Sea, where they are joined in late autumn and winter by the males that summered there (Fay 1982, Jay & Hills 2005.The Bering Sea has relatively steady-state sea ice conditions in winter until the disintegration and northward retreat of sea ice in spring (Burns et al. 1981). Regions of relatively homog...

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“…A conveyor belt mechanism, with a northern source, a southern sink, and an intermediate zone where ice is transported southward by northerly winds, has been proposed to explain the basic north-south structure using observations alone (Muench and Ahlnas, 1976;Pease, 1980). These satellite and in situ observations (Muench and Ahlnas, 1976;Pease, 1980;Wang et al, 2009;Stabeno et al, 2001), however, provide a limited perspective on what controls the seasonal extent and thickness of the ice. So numerical simulations are needed to better understand the dynamics and thermodynamics of these variations.…”

Section: Introductionmentioning

confidence: 99%

Processes driving sea ice variability in the Bering Sea in an eddying ocean/sea ice model: Mean seasonal cycle

McClean

Miller

et al. 2014

Ocean Modelling

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a b s t r a c tThe seasonal cycle of sea ice variability in the Bering Sea, together with the thermodynamic and dynamic processes that control it, are examined in a fine resolution (1/10°) global coupled ocean/sea-ice model configured in the Community Earth System Model (CESM) framework. The ocean/sea-ice model consists of the Los Alamos National Laboratory Parallel Ocean Program (POP) and the Los Alamos Sea Ice Model (CICE). The model was forced with time-varying reanalysis atmospheric forcing for the time period [1970][1971][1972][1973][1974][1975][1976][1977][1978][1979][1980][1981][1982][1983][1984][1985][1986][1987][1988][1989]. This study focuses on the time period 1980-1989. The simulated seasonal-mean fields of sea ice concentration strongly resemble satellite-derived observations, as quantified by root-meansquare errors and pattern correlation coefficients. The sea ice energy budget reveals that the seasonal thermodynamic ice volume changes are dominated by the surface energy flux between the atmosphere and the ice in the northern region and by heat flux from the ocean to the ice along the southern ice edge, especially on the western side. The sea ice force balance analysis shows that sea ice motion is largely associated with wind stress. The force due to divergence of the internal ice stress tensor is large near the land boundaries in the north, and it is small in the central and southern ice-covered region. During winter, which dominates the annual mean, it is found that the simulated sea ice was mainly formed in the northern Bering Sea, with the maximum ice growth rate occurring along the coast due to cold air from northerly winds and ice motion away from the coast. South of St Lawrence Island, winds drive the model sea ice southwestward from the north to the southwestern part of the ice-covered region. Along the ice edge in the western Bering Sea, model sea ice is melted by warm ocean water, which is carried by the simulated Bering Slope Current flowing to the northwest, resulting in the S-shaped asymmetric ice edge. In spring and fall, similar thermodynamic and dynamic patterns occur in the model, but with typically smaller magnitudes and with season-specific geographical and directional differences.

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Ice movement and distribution in the Bering Sea from March to June 1974

Cited by 56 publications

References 3 publications

Ecology and Biology of the Pacific Walrus,Odobenus rosmarus divergensIlliger

Ecology and Biology of the Pacific Walrus,Odobenus rosmarus divergensIlliger

Divergent movements of walrus and sea ice in the northern Bering Sea

Processes driving sea ice variability in the Bering Sea in an eddying ocean/sea ice model: Mean seasonal cycle

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