Lateral mixing across ice meltwater fronts of the Chukchi Sea shelf

Summer and fall hydrographic sections in the northeastern Chukchi Sea frequently capture 5–20 m thick intrapycnocline lenses or horizontal plumes of warm, moderately salty summer Bering Sea Water flowing northward from Bering Strait. These features occur within the shallow (~20 m depth) pycnocline s...

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Bibliographic Details
Published inGeophysical research letters Vol. 42; no. 16; pp. 6754 - 6761
Main Authors Lu, K., Weingartner, T., Danielson, S., Winsor, P., Dobbins, E., Martini, K., Statscewich, H.
Format Journal Article
LanguageEnglish
Published Washington Blackwell Publishing Ltd 28.08.2015
John Wiley & Sons, Inc
Subjects
Bering Sea
Chukchi Sea
Density stratification
Depth
Desalination
Dilution
Eddies
Freezing
Fronts
Heat
Heat flux
Heat transfer
Hydrographic sections
Ice
Ice formation
ice melt
Ice melting
Induction heating
Instability
lateral mixing
Lenses
Marine
Mathematical models
Meanders
Meltwater
meltwater fronts
Numerical models
Plumes
Pycnocline
Seawater
Shelves
Stability
Stratification
Summer
Surface stability
Temperature
Water
Winter
Bering Strait
INE, Chukchi Sea
INE, Bering Sea, Bering Strait
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Summary:Summer and fall hydrographic sections in the northeastern Chukchi Sea frequently capture 5–20 m thick intrapycnocline lenses or horizontal plumes of warm, moderately salty summer Bering Sea Water flowing northward from Bering Strait. These features occur within the shallow (~20 m depth) pycnocline separating cold, dilute, surface meltwater from near‐freezing, salty, winter‐formed waters beneath the pycnocline. An idealized numerical model suggests that the features arise from eddies and meanders generated by instability of the surface front separating meltwater from Bering Sea Water. Warm Bering Sea Water is transported across the front and into the pycnocline by the cross‐frontal velocities associated with the instabilities. The accompanying lateral eddy heat fluxes may be important both in summer for promoting ice melt and in fall by delaying the onset of ice formation over portions of this shelf. Lateral heat flux magnitudes depend upon the stratification of the Bering Sea Water. Key Points Unstable meltwater fronts form intrapycnocline eddies and induce lateral mixing These eddies may be an important heat and salt source to surface waters The subsurface heat could affect ice formation and ablation rates
Bibliography:istex:C7CC212DE39CD10A1D56A1294A98E0C148C346A4
ArticleID:GRL53332
NASA/GSFC/Earth Science Data and Information System (ESDIS)
NASA/HQ
ark:/67375/WNG-5PXMJVRS-8
Supporting Information S1
Land Atmosphere Near-real time Capability for EOS (LANCE)
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0094-8276
1944-8007
DOI:10.1002/2015GL064967