Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin

"A thesis presented to the faculty of Moss Landing Marine Laboratories." ABSTRACT: The partitioning of solar radiation entering the upper ocean in the presence of sea ice during the Arctic summer is essential to predicting future ice retreat. This study compares predicted incoming heat wit...

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Bibliographic Details
Main Author: Amanda Camarato
Other Authors: Thomas Connolly, Ivano Aiello, Tim Stanton
Format: Master Thesis
Language:English
Published: Moss Landing Marine Laboratories 2021
Subjects:
Arctic
Canada
canada basin
Sea ice
Online Access:https://hdl.handle.net/20.500.12680/8910k086h
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record_format openpolar
spelling ftcalifstateuniv:oai:scholarworks:8910k086h 2024-10-29T17:42:29+00:00 Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin Amanda Camarato Thomas Connolly Ivano Aiello Tim Stanton 2021 https://hdl.handle.net/20.500.12680/8910k086h English eng Moss Landing Marine Laboratories California State University, Monterey Bay http://hdl.handle.net/20.500.12680/8910k086h http://rightsstatements.org/vocab/InC/1.0/?creator Copyright by Amanda Camarato 2021 Masters Thesis 2021 ftcalifstateuniv https://doi.org/20.500.12680/8910k086h 2024-10-15T01:33:09Z "A thesis presented to the faculty of Moss Landing Marine Laboratories." ABSTRACT: The partitioning of solar radiation entering the upper ocean in the presence of sea ice during the Arctic summer is essential to predicting future ice retreat. This study compares predicted incoming heat with upper ocean density and thermal structure by constructing a simple, one-dimensional vertical heat budget around drifting buoy clusters deployed as part of the Stratified Ocean Dynamics of the Arctic experiment. Model reanalysis surface heat flux estimates were used with Synthetic Aperture Radar (SAR) and satellite radiometer derived open water fraction (OWF) estimates to construct an incoming surface heat flux budget. The incoming solar radiation forced upper-ocean heat gains, either stored locally or contributing to ice melt, through open water and the thinning ice cover. The estimated seasonal heat input directly through SAR-determined open water is roughly 44 MJ m-2, and the measured heat sinks total 104 MJ m-2 for mixed layer heat gain, basal melting, and basal conductance. Given the lack of sizeable advective heat sources, these results suggest that the residual heat source is through-ice transmittance. A transmission parameter was estimated from the residual heat flux and comparable to previous in situ observations of ice transmittance. These results suggest that through-ice transmittance is the dominating heat source around the observation site during the summer 2019 melt season. RELATED TITLE: Master Thesis canada basin Sea ice Scholarworks from California State University Arctic Canada
institution Open Polar
collection Scholarworks from California State University
op_collection_id ftcalifstateuniv
language English
description "A thesis presented to the faculty of Moss Landing Marine Laboratories." ABSTRACT: The partitioning of solar radiation entering the upper ocean in the presence of sea ice during the Arctic summer is essential to predicting future ice retreat. This study compares predicted incoming heat with upper ocean density and thermal structure by constructing a simple, one-dimensional vertical heat budget around drifting buoy clusters deployed as part of the Stratified Ocean Dynamics of the Arctic experiment. Model reanalysis surface heat flux estimates were used with Synthetic Aperture Radar (SAR) and satellite radiometer derived open water fraction (OWF) estimates to construct an incoming surface heat flux budget. The incoming solar radiation forced upper-ocean heat gains, either stored locally or contributing to ice melt, through open water and the thinning ice cover. The estimated seasonal heat input directly through SAR-determined open water is roughly 44 MJ m-2, and the measured heat sinks total 104 MJ m-2 for mixed layer heat gain, basal melting, and basal conductance. Given the lack of sizeable advective heat sources, these results suggest that the residual heat source is through-ice transmittance. A transmission parameter was estimated from the residual heat flux and comparable to previous in situ observations of ice transmittance. These results suggest that through-ice transmittance is the dominating heat source around the observation site during the summer 2019 melt season. RELATED TITLE:
author2 Thomas Connolly
Ivano Aiello
Tim Stanton
format Master Thesis
author Amanda Camarato
spellingShingle Amanda Camarato
Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin
author_facet Amanda Camarato
author_sort Amanda Camarato
title Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin
title_short Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin
title_full Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin
title_fullStr Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin
title_full_unstemmed Satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the Canada basin
title_sort satellite remote sensing & model reanalysis estimates of upper-ocean heat content in the canada basin
publisher Moss Landing Marine Laboratories
publishDate 2021
url https://hdl.handle.net/20.500.12680/8910k086h
geographic Arctic
Canada
geographic_facet Arctic
Canada
genre canada basin
Sea ice
genre_facet canada basin
Sea ice
op_relation http://hdl.handle.net/20.500.12680/8910k086h
op_rights http://rightsstatements.org/vocab/InC/1.0/?creator
Copyright by Amanda Camarato 2021
op_doi https://doi.org/20.500.12680/8910k086h
_version_ 1814279659865505792

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