James H. Swift scite author profile

Phytoplankton blooms over Arctic Ocean continental shelves are thought to be restricted to waters free of sea ice. Here, we document a massive phytoplankton bloom beneath fully consolidated pack ice far from the ice edge in the Chukchi Sea, where light transmission has increased in recent decades because of thinning ice cover and proliferation of melt ponds. The bloom was characterized by high diatom biomass and rates of growth and primary production. Evidence suggests that under-ice phytoplankton blooms may be more widespread over nutrient-rich Arctic continental shelves and that satellite-based estimates of annual primary production in these waters may be underestimated by up to 10-fold.

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Thermohaline circulation in the Arctic Mediterranean Seas

Aagaard¹,

Swift²,

Carmack³

1985

J. Geophys. Res.

701

423

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The renewal of the deep North Atlantic by the various overflows of the Greenland‐Scotland ridges is only one manifestation of the convective and mixing processes which occur in the various basins and shelf areas to the north: the Arctic Ocean and the Greenland, Iceland, and Norwegian seas, collectively called the Arctic Mediterranean. The traditional site of deep ventilation for these basins is the Greenland Sea, but a growing body of evidence also points to the Arctic Ocean as a major source of deep water. This deep water is relatively warm and saline, and it appears to be a mixture of dense, brine‐enriched shelf water with intermediate strata in the Arctic Ocean. The deep water exits the Arctic Ocean along the Greenland slope to mix with the Greenland Sea deep water. Conversely, very cold low‐salinity deep water from the Greenland Sea enters the Arctic Ocean west of Spitsbergen. Within the Arctic Ocean, the Lomonosov Ridge excludes the Greenland Sea deep water from the Canadian Basin, leaving the latter warm, saline, and rich in silica. In general, the entire deep‐water sphere of the Arctic Mediterranean is constrained by the Greenland‐Scotland ridges to circulate internally. Therefore it is certain of the intermediate waters formed in the Greenland and Iceland seas which ventilate the North Atlantic. These waters have a very short residence time in their formation areas and are therefore able to rapidly transmit surface‐induced signals into the deep North Atlantic.

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Long-term coordinated changes in the convective activity of the North Atlantic

Dickson

Lazier

Meincke

et al. 1996

Progress in Oceanography

594

375

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The GEOTRACES Intermediate Data Product 2017

et al. 2018

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Distribution of Atlantic and Pacific waters in the upper Arctic Ocean: Implications for circulation

Jones

Anderson

Swift

1998

Geophysical Research Letters

238

306

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River runoff, sea ice meltwater, and Pacific water distribution and mean residence times in the Arctic Ocean

Ekwurzel¹,

Schlosser²,

Mortlock³

et al. 2001

J. Geophys. Res.

227

272

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Introduction to Descriptive Physical Oceanography

Talley¹,

Pickard²,

Emery³

et al. 2011

451

272

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Tracing Pacific water in the North Atlantic Ocean

et al. 2003

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In the Arctic Ocean, Pacific source water can be distinguished from Atlantic source water by nitrate‐phosphate concentration relationships, with Pacific water having higher phosphate concentrations relative to those of nitrate. Furthermore, Pacific water, originally from the inflow through Bering Strait, is clearly recognizable in the outflows of low‐salinity waters from the Arctic Ocean to the northern North Atlantic Ocean through the Canadian Arctic Archipelago and through Fram Strait. In the Canadian Arctic Archipelago, we observe that almost all of the waters flowing through Lancaster and Jones sounds, most of the water in the top 100 m in Smith Sound (containing the flow through Nares Strait), and possibly all waters in Hudson Bay contain no water of Atlantic origin. Significant amounts of Pacific water are also observed along the western coast of Baffin Bay, along the coast of Labrador, and above the 200‐m isobath of the Grand Banks. There is a clear signal of Pacific water flowing south through Fram Strait and along the east coast of Greenland extending at least as far south as Denmark Strait. Pacific water signature can be seen near the east coast of Greenland at 66°N, but not in data at 60°N. Temporal variability in the concentrations of Pacific water has been observed at several locations where multiple‐year observations are available.

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James H. Swift

Massive Phytoplankton Blooms Under Arctic Sea Ice

Thermohaline circulation in the Arctic Mediterranean Seas

Long-term coordinated changes in the convective activity of the North Atlantic

The GEOTRACES Intermediate Data Product 2017

Distribution of Atlantic and Pacific waters in the upper Arctic Ocean: Implications for circulation

River runoff, sea ice meltwater, and Pacific water distribution and mean residence times in the Arctic Ocean

Introduction to Descriptive Physical Oceanography

Tracing Pacific water in the North Atlantic Ocean

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