Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic

Summer sea ice extent in the Western Arctic has decreased significantly in recent years resulting in increased solar input into the upper ocean. Here, a comprehensive set of in situshipboard, on-ice, and autonomous ice-ocean measurements were made of the early stages of formation of the near-surface...

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Published in:	Elementa: Science of the Anthropocene
Main Authors:	Gallaher, Shawn G., Stanton, Timothy P., Shaw, William J., Kang, Sung-Ho, Kim, Joo-Hong, Cho, Kyoung-Ho
Other Authors:	Deming, Jody W., Lee, Craig M.
Format:	Article in Journal/Newspaper
Language:	English
Published:	University of California Press 2017
Subjects:	Atmospheric Science Geology Geotechnical Engineering and Engineering Geology Ecology Environmental Engineering Oceanography Arctic Canada canada basin Sea ice
Online Access:	http://dx.doi.org/10.1525/elementa.195 http://online.ucpress.edu/elementa/article-pdf/doi/10.1525/elementa.195/472445/195-2665-5-pb.pdf

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spelling	crunicaliforniap:10.1525/elementa.195 2023-11-12T04:12:48+01:00 Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic Gallaher, Shawn G. Stanton, Timothy P. Shaw, William J. Kang, Sung-Ho Kim, Joo-Hong Cho, Kyoung-Ho Deming, Jody W. Lee, Craig M. 2017 http://dx.doi.org/10.1525/elementa.195 http://online.ucpress.edu/elementa/article-pdf/doi/10.1525/elementa.195/472445/195-2665-5-pb.pdf en eng University of California Press http://creativecommons.org/licenses/by/4.0/ Elementa: Science of the Anthropocene volume 5 ISSN 2325-1026 Atmospheric Science Geology Geotechnical Engineering and Engineering Geology Ecology Environmental Engineering Oceanography journal-article 2017 crunicaliforniap https://doi.org/10.1525/elementa.195 2023-10-15T17:42:46Z Summer sea ice extent in the Western Arctic has decreased significantly in recent years resulting in increased solar input into the upper ocean. Here, a comprehensive set of in situshipboard, on-ice, and autonomous ice-ocean measurements were made of the early stages of formation of the near-surface temperature maximum (NSTM) in the Canada Basin. These observations along with the results from a 1-D turbulent boundary layer model indicate that heat storage associated with NSTM formation is largely due to the absorption of penetrating solar radiation just below a protective summer halocline. The depth of the summer halocline was found to be the most important factor for determining the amount of solar radiation absorbed in the NSTM layer, while halocline strength controlled the amount of heat removed from the NSTM by turbulent transport. Observations using the Naval Postgraduate School Turbulence Frame show that the NSTM was able to persist despite periods of intermittent turbulence because transport rates were too small to remove significant amounts of heat from the NSTM layer. The development of the early and late summer halocline and NSTM were found to be linked to summer season buoyancy and wind events. For the early summer NSTM, 1-D boundary layer model results show that melt pond drainage provides sufficient buoyancy to the summer halocline to prevent subsequent wind events from mixing out the NSTM. For the late summer NSTM,limited freshwater inputs reduce the strength of the summer halocline making the balance between interfacial stresses and buoyancy more tenuous. As a result, the late summer NSTM is an ephemeral feature dependent on local wind conditions, while the early summer NSTM is more persistent and able to store heat in the near-surface ocean beyond the summer season. Article in Journal/Newspaper Arctic canada basin Sea ice University of California Press (via Crossref) Arctic Canada Elementa: Science of the Anthropocene 5
institution	Open Polar
collection	University of California Press (via Crossref)
op_collection_id	crunicaliforniap
language	English
topic	Atmospheric Science Geology Geotechnical Engineering and Engineering Geology Ecology Environmental Engineering Oceanography
spellingShingle	Atmospheric Science Geology Geotechnical Engineering and Engineering Geology Ecology Environmental Engineering Oceanography Gallaher, Shawn G. Stanton, Timothy P. Shaw, William J. Kang, Sung-Ho Kim, Joo-Hong Cho, Kyoung-Ho Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic
topic_facet	Atmospheric Science Geology Geotechnical Engineering and Engineering Geology Ecology Environmental Engineering Oceanography
description	Summer sea ice extent in the Western Arctic has decreased significantly in recent years resulting in increased solar input into the upper ocean. Here, a comprehensive set of in situshipboard, on-ice, and autonomous ice-ocean measurements were made of the early stages of formation of the near-surface temperature maximum (NSTM) in the Canada Basin. These observations along with the results from a 1-D turbulent boundary layer model indicate that heat storage associated with NSTM formation is largely due to the absorption of penetrating solar radiation just below a protective summer halocline. The depth of the summer halocline was found to be the most important factor for determining the amount of solar radiation absorbed in the NSTM layer, while halocline strength controlled the amount of heat removed from the NSTM by turbulent transport. Observations using the Naval Postgraduate School Turbulence Frame show that the NSTM was able to persist despite periods of intermittent turbulence because transport rates were too small to remove significant amounts of heat from the NSTM layer. The development of the early and late summer halocline and NSTM were found to be linked to summer season buoyancy and wind events. For the early summer NSTM, 1-D boundary layer model results show that melt pond drainage provides sufficient buoyancy to the summer halocline to prevent subsequent wind events from mixing out the NSTM. For the late summer NSTM,limited freshwater inputs reduce the strength of the summer halocline making the balance between interfacial stresses and buoyancy more tenuous. As a result, the late summer NSTM is an ephemeral feature dependent on local wind conditions, while the early summer NSTM is more persistent and able to store heat in the near-surface ocean beyond the summer season.
author2	Deming, Jody W. Lee, Craig M.
format	Article in Journal/Newspaper
author	Gallaher, Shawn G. Stanton, Timothy P. Shaw, William J. Kang, Sung-Ho Kim, Joo-Hong Cho, Kyoung-Ho
author_facet	Gallaher, Shawn G. Stanton, Timothy P. Shaw, William J. Kang, Sung-Ho Kim, Joo-Hong Cho, Kyoung-Ho
author_sort	Gallaher, Shawn G.
title	Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic
title_short	Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic
title_full	Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic
title_fullStr	Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic
title_full_unstemmed	Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic
title_sort	field observations and results of a 1-d boundary layer model for developing near-surface temperature maxima in the western arctic
publisher	University of California Press
publishDate	2017
url	http://dx.doi.org/10.1525/elementa.195 http://online.ucpress.edu/elementa/article-pdf/doi/10.1525/elementa.195/472445/195-2665-5-pb.pdf
geographic	Arctic Canada
geographic_facet	Arctic Canada
genre	Arctic canada basin Sea ice
genre_facet	Arctic canada basin Sea ice
op_source	Elementa: Science of the Anthropocene volume 5 ISSN 2325-1026
op_rights	http://creativecommons.org/licenses/by/4.0/
op_doi	https://doi.org/10.1525/elementa.195
container_title	Elementa: Science of the Anthropocene
container_volume	5
_version_	1782331134046109696

Field observations and results of a 1-D boundary layer model for developing near-surface temperature maxima in the Western Arctic

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