Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean

Decrease in Arctic Ocean perennial sea-ice has been observed in recent decades. As sea-ice continues to decline, marine traffic will increase and the United States will require a more active military presence in the Arctic. Future Arctic conditions must be forecasted with increased accuracy to allow...

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Bibliographic Details
Main Author:	Schmidt, Brandon K.
Other Authors:	Stanton, Timothy, Physical Oceanography, Shaw, William
Format:	Thesis
Language:	unknown
Published:	Monterey, California. Naval Postgraduate School 2012
Subjects:	Arctic Ocean Beaufort Sea Ice Concentration Ice Morphology Ice Roughness Sea Ice Ice Keel Mixed Layer Turbulence Ocean Heat Flux Mixing Length Dissipation Rate Drag Coefficient Arctic Sea ice
Online Access:	https://hdl.handle.net/10945/6864

id	ftnavalpschool:oai:calhoun.nps.edu:10945/6864
record_format	openpolar
spelling	ftnavalpschool:oai:calhoun.nps.edu:10945/6864 2024-06-09T07:43:27+00:00 Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean Schmidt, Brandon K. Stanton, Timothy Physical Oceanography Shaw, William 2012-03 application/pdf https://hdl.handle.net/10945/6864 unknown Monterey, California. Naval Postgraduate School https://hdl.handle.net/10945/6864 Arctic Ocean Beaufort Sea Ice Concentration Ice Morphology Ice Roughness Sea Ice Ice Keel Mixed Layer Turbulence Ocean Heat Flux Mixing Length Dissipation Rate Drag Coefficient Thesis 2012 ftnavalpschool 2024-05-15T00:20:53Z Decrease in Arctic Ocean perennial sea-ice has been observed in recent decades. As sea-ice continues to decline, marine traffic will increase and the United States will require a more active military presence in the Arctic. Future Arctic conditions must be forecasted with increased accuracy to allow for proper planning with regard to the nations changing role in the region. It is the goal of this thesis to contribute to the knowledge of turbulence and mixing associated with ice keels in the Arctic Ocean in order to improve the accuracy of predictive coupled ocean/ice/atmospheric models. At Applied Physics Laboratory Ice Station 2011, a 3-dimensional (3-D) sonar was used to record high resolution morphological measurements of an ice keel approximately 33 m long by 29 m across and 10 m deep. Sensors were deployed in the water column approximately 10 m from the keel to record water properties of salinity, temperature, and 3-D velocity at selected depths in the upper water column. These observations were used to make calculations of turbulence within the mixed layer, in order to gain a greater understanding of how keels affect turbulent drag and heat fluxes in the upper ocean. Results indicate that keels generate significant turbulence and mixing in the upper ocean, even during benign weather conditions in which there is little surface forcing. Keels increase the kinetic energy of the upper ocean through production of turbulent eddies during times of weak stratification and the generation of internal waves during times of strong stratification. Keel-induced turbulence and mixing may lead to entrainment of warmer water underlying the surface mixed layer that could be a contributor to ice melting. Calculation of the quadratic drag coefficient Cw also indicated that Cw varies greatly with water column stratification and ice undersurface roughness. Values as high as 0.08 were seen in the wake of a 10 m ice keel during strong stratification, and as low as 0.002 when the current was not affected by the keel during weak ... Thesis Arctic Arctic Ocean Beaufort Sea Sea ice Naval Postgraduate School: Calhoun Arctic Arctic Ocean
institution	Open Polar
collection	Naval Postgraduate School: Calhoun
op_collection_id	ftnavalpschool
language	unknown
topic	Arctic Ocean Beaufort Sea Ice Concentration Ice Morphology Ice Roughness Sea Ice Ice Keel Mixed Layer Turbulence Ocean Heat Flux Mixing Length Dissipation Rate Drag Coefficient
spellingShingle	Arctic Ocean Beaufort Sea Ice Concentration Ice Morphology Ice Roughness Sea Ice Ice Keel Mixed Layer Turbulence Ocean Heat Flux Mixing Length Dissipation Rate Drag Coefficient Schmidt, Brandon K. Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean
topic_facet	Arctic Ocean Beaufort Sea Ice Concentration Ice Morphology Ice Roughness Sea Ice Ice Keel Mixed Layer Turbulence Ocean Heat Flux Mixing Length Dissipation Rate Drag Coefficient
description	Decrease in Arctic Ocean perennial sea-ice has been observed in recent decades. As sea-ice continues to decline, marine traffic will increase and the United States will require a more active military presence in the Arctic. Future Arctic conditions must be forecasted with increased accuracy to allow for proper planning with regard to the nations changing role in the region. It is the goal of this thesis to contribute to the knowledge of turbulence and mixing associated with ice keels in the Arctic Ocean in order to improve the accuracy of predictive coupled ocean/ice/atmospheric models. At Applied Physics Laboratory Ice Station 2011, a 3-dimensional (3-D) sonar was used to record high resolution morphological measurements of an ice keel approximately 33 m long by 29 m across and 10 m deep. Sensors were deployed in the water column approximately 10 m from the keel to record water properties of salinity, temperature, and 3-D velocity at selected depths in the upper water column. These observations were used to make calculations of turbulence within the mixed layer, in order to gain a greater understanding of how keels affect turbulent drag and heat fluxes in the upper ocean. Results indicate that keels generate significant turbulence and mixing in the upper ocean, even during benign weather conditions in which there is little surface forcing. Keels increase the kinetic energy of the upper ocean through production of turbulent eddies during times of weak stratification and the generation of internal waves during times of strong stratification. Keel-induced turbulence and mixing may lead to entrainment of warmer water underlying the surface mixed layer that could be a contributor to ice melting. Calculation of the quadratic drag coefficient Cw also indicated that Cw varies greatly with water column stratification and ice undersurface roughness. Values as high as 0.08 were seen in the wake of a 10 m ice keel during strong stratification, and as low as 0.002 when the current was not affected by the keel during weak ...
author2	Stanton, Timothy Physical Oceanography Shaw, William
format	Thesis
author	Schmidt, Brandon K.
author_facet	Schmidt, Brandon K.
author_sort	Schmidt, Brandon K.
title	Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean
title_short	Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean
title_full	Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean
title_fullStr	Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean
title_full_unstemmed	Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean
title_sort	observations of hydraulic roughness and form drag in the wake of a deep ice keel in the arctic ocean
publisher	Monterey, California. Naval Postgraduate School
publishDate	2012
url	https://hdl.handle.net/10945/6864
geographic	Arctic Arctic Ocean
geographic_facet	Arctic Arctic Ocean
genre	Arctic Arctic Ocean Beaufort Sea Sea ice
genre_facet	Arctic Arctic Ocean Beaufort Sea Sea ice
op_relation	https://hdl.handle.net/10945/6864
_version_	1801372276145258496

Observations of Hydraulic Roughness and Form Drag in the Wake of a Deep Ice Keel in the Arctic Ocean

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