The Winter Heat Budget of Sea Ice in Kotzebue Sound: Residual Ocean Heat and the Seasonal Roles of River Outflow

Heat budget studies of the sea ice cover near Pond Inlet, NWT, were made using data obtained at two locations in Eclipse Sound, one about 0.5 km from shore and the other about 7.5 km from shore. The observations at intervals of one week included ice temperatures at 10 cm separation in vertical profile, salinities of adjacent 2.5 cm-thick slices from vertical ice cores, and ice thickness. The time series analysed extend from three to six months in the six data sets obtained for three winters of observations. Values of oceanic heat flux have been determined as residuals in the energy balance equation applied to the ice cover. The results show that in Eclipse Sound the oceanic heat flux is a significant component of the heat budget of the ice cover. Its value over the winter is typically about 6 W m-2about half as large as the average rate of release of the latent heat of freezing. There does not appear to be any systematic variation in value of the 4 week-average oceanic heat flux during the season. Nor is there any apparent correlation of oceanic heat flux with rate of release of latent heat (ie ice growth rate), or with the severity of the winter as measured by the magnitude of the conductive heat flux.

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A Numerical Investigation of Formation and Variability of Antarctic Bottom Water off Cape Darnley, East Antarctica

Journal of Physical Oceanography ◽

10.1175/jpo-d-14-0069.1 ◽

2014 ◽

Vol 44 (11) ◽

pp. 2921-2937 ◽

Cited By ~ 14

Author(s):

Yoshihiro Nakayama ◽

Kay I. Ohshima ◽

Yoshimasa Matsumura ◽

Yasushi Fukamachi ◽

Hiroyasu Hasumi

Keyword(s):

Sea Ice ◽

Continental Slope ◽

Bottom Water ◽

Heat Budget ◽

East Antarctica ◽

Salt Flux ◽

Ice Formation ◽

Minor Importance ◽

Antarctic Bottom Water ◽

Dense Water

Abstract At several locations around Antarctica, dense water is formed as a result of intense sea ice formation. When this dense water becomes sufficiently denser than the surrounding water, it descends the continental slope and forms Antarctic Bottom Water (AABW). This study presents the AABW formation off the coast of Cape Darnley [Cape Darnley Bottom Water (CDBW)] in East Antarctica, using a nonhydrostatic model. The model is forced for 8 months by a temporally uniform surface salt flux (because of sea ice formation) estimated from Advanced Microwave Scanning Radiometer for Earth Observing System (EOS; AMSR-E) data and a heat budget calculation. The authors reproduce AABW formation and associated periodic downslope flows of dense water. Descending pathways of dense water are largely determined by the topography; most dense water flows into depressions on the continental shelf, advects onto the continental slope, and is steered downslope to greater depths by the canyons. Intense sea ice formation is the most important factor in the formation of AABW off Cape Darnley, and the existence of depressions is of only minor importance for the flux of CDBW. The mechanism responsible for the periodic downslope flow of dense water is further analyzed using an idealized model setup. The period of dense water outflow is regulated primarily by the topographic beta effect.

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Seasonal changes in Arctic sea-ice morphology

Annals of Glaciology ◽

10.3189/172756401781818716 ◽

2001 ◽

Vol 33 ◽

pp. 171-176 ◽

Cited By ~ 16

Author(s):

Donald K. Perovich ◽

Jacqueline A. Richter-Menge ◽

Walter B. Tucker

Keyword(s):

Sea Ice ◽

Heat Budget ◽

Open Water ◽

Ice Cover ◽

Arctic Sea Ice ◽

The Arctic ◽

Ice Surface ◽

Arctic Sea ◽

Dynamic Forcing ◽

Break Up

AbstractThe morphology of the Arctic sea-ice cover undergoes large changes over an annual cycle. These changes have a significant impact on the heat budget of the ice cover, primarily by affecting the distribution of the solar radiation absorbed in the ice-ocean system. In spring, the ice is snow-covered and ridges are the prominent features. The pack consists of large angular floes, with a small amount of open water contained primarily in linear leads. By the end of summer the ice cover has undergone a major transformation. The snow cover is gone, many of the ridges have been reduced to hummocks and the ice surface is mottled with melt ponds. One surface characteristic that changes little during the summer is the appearance of the bare ice, which remains white despite significant melting. The large floes have broken into a mosaic of smaller, rounded floes surrounded by a lace of open water. Interestingly, this break-up occurs during summer when the dynamic forcing and the internal ice stress are small During the Surface Heat Budget of the Arctic Ocean (SHEBA) field experiment we had an opportunity to observe the break-up process both on a small scale from the ice surface, and on a larger scale via aerial photographs. Floe break-up resulted in large part from thermal deterioration of the ice. The large floes of spring are riddled with cracks and leads that formed and froze during fall, winter and spring. These features melt open during summer, weakening the ice so that modest dynamic forcing can break apart the large floes into many fragments. Associated with this break-up is an increase in the number of floes, a decrease in the size of floes, an increase in floe perimeter and an increase in the area of open water.

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The Granular Sea Ice Model in Spherical Coordinates and Its Application to a Global Climate Model

Journal of Climate ◽

10.1175/2007jcli1664.1 ◽

2007 ◽

Vol 20 (24) ◽

pp. 5946-5961 ◽

Cited By ~ 7

Author(s):

Jan Sedlacek ◽

Jean-François Lemieux ◽

Lawrence A. Mysak ◽

L. Bruno Tremblay ◽

David M. Holland

Keyword(s):

Growth Rate ◽

Sea Ice ◽

Climate Model ◽

Heat Budget ◽

Global Climate ◽

Global Climate Model ◽

Internal Heat ◽

The Arctic ◽

Spherical Coordinates ◽

Ice Model

Abstract The granular sea ice model (GRAN) from Tremblay and Mysak is converted from Cartesian to spherical coordinates. In this conversion, the metric terms in the divergence of the deviatoric stress and in the strain rates are included. As an application, the GRAN is coupled to the global Earth System Climate Model from the University of Victoria. The sea ice model is validated against standard datasets. The sea ice volume and area exported through Fram Strait agree well with values obtained from in situ and satellite-derived estimates. The sea ice velocity in the interior Arctic agrees well with buoy drift data. The thermodynamic behavior of the sea ice model over a seasonal cycle at one location in the Beaufort Sea is validated against the Surface Heat Budget of the Arctic Ocean (SHEBA) datasets. The thermodynamic growth rate in the model is almost twice as large as the observed growth rate, and the melt rate is 25% lower than observed. The larger growth rate is due to thinner ice at the beginning of the SHEBA period and the absence of internal heat storage in the ice layer in the model. The simulated lower summer melt is due to the smaller-than-observed surface melt.

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Calculations of temperature regime and heat budget of sea ice in the central Arctic

Deep Sea Research and Oceanographic Abstracts ◽

10.1016/0011-7471(65)90755-2 ◽

1965 ◽

Vol 12 (4) ◽

pp. 642

Keyword(s):

Sea Ice ◽

Temperature Regime ◽

Heat Budget

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Creation of a Heat and Salt Flux Dataset Associated with Sea Ice Production and Melting in the Sea of Okhotsk

Journal of Climate ◽

10.1175/jcli-d-11-00022.1 ◽

2012 ◽

Vol 25 (7) ◽

pp. 2261-2278 ◽

Cited By ~ 23

Author(s):

Sohey Nihashi ◽

Kay I. Ohshima ◽

Noriaki Kimura

Keyword(s):

Spatial Distribution ◽

Sea Ice ◽

Sea Of Okhotsk ◽

Heat Budget ◽

Salt Flux ◽

The Sea Of Okhotsk ◽

Ice Melt ◽

Budget Analysis ◽

Coastal Polynya ◽

Ice Production

Abstract Sea ice formation, its transport, and its melting cause the redistribution of heat and salt, which plays an important role in the climate and biogeochemical systems. In the Sea of Okhotsk, a heat and salt flux dataset is created in which such sea ice processes are included, with a spatial resolution of ~12.5 km. The dataset is based on a heat budget analysis using ice concentration, thickness, and drift speed from satellite observations and the ECMWF Interim Re-Analysis (ERA-Interim) data. The salt flux calculation considers both salt supplied to the ocean from sea ice production and freshwater supplied when the ice melts. This dataset will be useful for the validation and boundary conditions of modeling studies. The spatial distribution of the annual fluxes shows a distinct contrast between north and south: significant ocean cooling with salt supply is shown in the northern coastal polynya region, while ocean heating with freshwater supply is shown in the south. This contrast suggests a transport of freshwater and negative heat by ice advection. The annual fluxes also show ocean cooling with freshwater supply in the Kashevarov Bank (KB) region and the central and eastern Sea of Okhotsk, suggesting the effect of warm water advection. In the ice melt season, relatively prominent ice melting is shown in the coastal polynya region, probably due to large solar heating of the upper ocean. This indicates that the polynya works as a “meltwater factory” in spring, contrasting with its role as an “ice factory” in winter. In the coastal polynya region, the spatial distribution of phytoplankton bloom roughly corresponds with the ice melt region.

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Meltwater sources and sinks for multiyear Arctic sea ice in summer

The Cryosphere ◽

10.5194/tc-15-4517-2021 ◽

2021 ◽

Vol 15 (9) ◽

pp. 4517-4525

Author(s):

Don Perovich ◽

Madison Smith ◽

Bonnie Light ◽

Melinda Webster

Keyword(s):

Sea Ice ◽

Heat Budget ◽

Arctic Sea Ice ◽

Sources And Sinks ◽

Ice Melt ◽

Ice Surface ◽

Melt Ponds ◽

Arctic Sea ◽

Ice Mass Balance ◽

Surface Heat Budget

Abstract. On Arctic sea ice, the melt of snow and sea ice generate a summertime flux of fresh water to the upper ocean. The partitioning of this meltwater to storage in melt ponds and deposition in the ocean has consequences for the surface heat budget, the sea ice mass balance, and primary productivity. Synthesizing results from the 1997–1998 SHEBA field experiment, we calculate the sources and sinks of meltwater produced on a multiyear floe during summer melt. The total meltwater input to the system from snowmelt, ice melt, and precipitation from 1 June to 9 August was equivalent to a layer of water 80 cm thick over the ice-covered and open ocean. A total of 85 % of this meltwater was deposited in the ocean, and only 15 % of this meltwater was stored in ponds. The cumulative contributions of meltwater input to the ocean from drainage from the ice surface and bottom melting were roughly equal.

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Thin ice, deep snow and surface flooding in Kotzebue Sound: landfast ice mass balance during two anomalously warm winters and implications for marine mammals and subsistence hunting

Journal of Glaciology ◽

10.1017/jog.2021.49 ◽

2021 ◽

pp. 1-15

Author(s):

Andrew R. Mahoney ◽

Kate E. Turner ◽

Donna D. W. Hauser ◽

Nathan J. M. Laxague ◽

Jessica M. Lindsay ◽

...

Keyword(s):

Heat Flux ◽

Sea Ice ◽

Mass Balance ◽

Marine Mammals ◽

Advisory Council ◽

Subsistence Hunting ◽

Ice Growth ◽

Landfast Ice ◽

Ice Mass Balance ◽

Kotzebue Sound

Abstract The inaugural data from the first systematic program of sea-ice observations in Kotzebue Sound, Alaska, in 2018 coincided with the first winter in living memory when the Sound was not choked with ice. The following winter of 2018–19 was even warmer and characterized by even less ice. Here we discuss the mass balance of landfast ice near Kotzebue (Qikiqtaġruk) during these two anomalously warm winters. We use in situ observations and a 1-D thermodynamic model to address three research questions developed in partnership with an Indigenous Advisory Council. In doing so, we improve our understanding of connections between landfast ice mass balance, marine mammals and subsistence hunting. Specifically, we show: (i) ice growth stopped unusually early due to strong vertical ocean heat flux, which also likely contributed to early start to bearded seal hunting; (ii) unusually thin ice contributed to widespread surface flooding. The associated snow ice formation partly offset the reduced ice growth, but the flooding likely had a negative impact on ringed seal habitat; (iii) sea ice near Kotzebue during the winters of 2017–18 and 2018–19 was likely the thinnest since at least 1945, driven by a combination of warm air temperatures and a persistent ocean heat flux.

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