Ice-ocean interactions in Milne Fiord

Widespread break up of ice shelves, glacier tongues, and the loss of ice-dammed epishelf lakes on the northern coast of Ellesmere Island has motivated a need to understand fjord dynamics, yet the oceanography of fjords here is not well studied. Here, we present ocean profiling and mooring data colle...

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Bibliographic Details
Main Author: Hamilton, Andrew Kent
Format: Thesis
Language:English
Published: University of British Columbia 2016
Subjects:
Arctic
Ellesmere Island
Milne Ice Shelf
Milne Fiord
Milne Glacier
Ice Shelf
Ice Shelves
Online Access:http://hdl.handle.net/2429/59051
id ftunivbritcolcir:oai:circle.library.ubc.ca:2429/59051
record_format openpolar
spelling ftunivbritcolcir:oai:circle.library.ubc.ca:2429/59051 2023-05-15T15:17:18+02:00 Ice-ocean interactions in Milne Fiord Hamilton, Andrew Kent 2016 http://hdl.handle.net/2429/59051 eng eng University of British Columbia Attribution-NonCommercial-NoDerivatives 4.0 International http://creativecommons.org/licenses/by-nc-nd/4.0/ CC-BY-NC-ND Text Thesis/Dissertation 2016 ftunivbritcolcir 2019-10-15T18:21:08Z Widespread break up of ice shelves, glacier tongues, and the loss of ice-dammed epishelf lakes on the northern coast of Ellesmere Island has motivated a need to understand fjord dynamics, yet the oceanography of fjords here is not well studied. Here, we present ocean profiling and mooring data collected from 2011 to 2015 in Milne Fiord, the last ice shelf-epishelf lake-glacier tongue fjord in the Arctic. The data reveal that seasonal and interannual variations of fjord water properties and circulation are strongly impacted by the presence of the Milne Ice Shelf. The ice shelf forms a floating dam that traps surface runoff resulting in strong stratification and an elevated fjord heat content. Water exchange below the ice shelf is restricted to a narrow basal channel, prolonging the export of fjord-modified water, including subglacial runoff, by several months. In contrast, intermediate waters that penetrate to the Milne Glacier grounding line are freely exchanged and respond to offshore variations, with implications for submarine melting. Unexpectedly, the depth of the halocline between the epishelf lake and seawater, often used to infer the thickness of the ice shelf, varied by several meters each year. This variability resulted from rapid inflow of surface runoff during summer followed by slow drainage under the ice shelf over winter, which is well modelled as hydraulically-controlled flow through a channel. A mixing event also abruptly changed the depth of the halocline by 1.5 m in less than 24 hours, indicating caution must be used when inferring ice shelf mass balance from halocline depth. Submarine melt rates, estimated by two independent approaches, are strongly dependent on the vertical distribution of heat in the fjord. Spatial variation of ice thickness resulted in a heterogeneous distribution of melt. The highest estimated melt rate (4 m/a) occurred where the glacier was in contact with warm AtlanticWater at the grounding line, and enhanced near-surface melting is driven by the elevated heat content of the upper water column. Estimated melt rates are limited by weak currents ( 1 cm/s) in the fjord imposed by the presence of the ice shelf. Applied Science, Faculty of Civil Engineering, Department of Graduate Thesis Arctic Ellesmere Island Ice Shelf Ice Shelves Milne Fiord Milne Ice Shelf University of British Columbia: cIRcle - UBC's Information Repository Arctic Ellesmere Island Milne Ice Shelf ENVELOPE(-81.747,-81.747,82.736,82.736) Milne Fiord ENVELOPE(-81.447,-81.447,82.636,82.636) Milne Glacier ENVELOPE(-79.997,-79.997,82.402,82.402)
institution Open Polar
collection University of British Columbia: cIRcle - UBC's Information Repository
op_collection_id ftunivbritcolcir
language English
description Widespread break up of ice shelves, glacier tongues, and the loss of ice-dammed epishelf lakes on the northern coast of Ellesmere Island has motivated a need to understand fjord dynamics, yet the oceanography of fjords here is not well studied. Here, we present ocean profiling and mooring data collected from 2011 to 2015 in Milne Fiord, the last ice shelf-epishelf lake-glacier tongue fjord in the Arctic. The data reveal that seasonal and interannual variations of fjord water properties and circulation are strongly impacted by the presence of the Milne Ice Shelf. The ice shelf forms a floating dam that traps surface runoff resulting in strong stratification and an elevated fjord heat content. Water exchange below the ice shelf is restricted to a narrow basal channel, prolonging the export of fjord-modified water, including subglacial runoff, by several months. In contrast, intermediate waters that penetrate to the Milne Glacier grounding line are freely exchanged and respond to offshore variations, with implications for submarine melting. Unexpectedly, the depth of the halocline between the epishelf lake and seawater, often used to infer the thickness of the ice shelf, varied by several meters each year. This variability resulted from rapid inflow of surface runoff during summer followed by slow drainage under the ice shelf over winter, which is well modelled as hydraulically-controlled flow through a channel. A mixing event also abruptly changed the depth of the halocline by 1.5 m in less than 24 hours, indicating caution must be used when inferring ice shelf mass balance from halocline depth. Submarine melt rates, estimated by two independent approaches, are strongly dependent on the vertical distribution of heat in the fjord. Spatial variation of ice thickness resulted in a heterogeneous distribution of melt. The highest estimated melt rate (4 m/a) occurred where the glacier was in contact with warm AtlanticWater at the grounding line, and enhanced near-surface melting is driven by the elevated heat content of the upper water column. Estimated melt rates are limited by weak currents ( 1 cm/s) in the fjord imposed by the presence of the ice shelf. Applied Science, Faculty of Civil Engineering, Department of Graduate
format Thesis
author Hamilton, Andrew Kent
spellingShingle Hamilton, Andrew Kent
Ice-ocean interactions in Milne Fiord
author_facet Hamilton, Andrew Kent
author_sort Hamilton, Andrew Kent
title Ice-ocean interactions in Milne Fiord
title_short Ice-ocean interactions in Milne Fiord
title_full Ice-ocean interactions in Milne Fiord
title_fullStr Ice-ocean interactions in Milne Fiord
title_full_unstemmed Ice-ocean interactions in Milne Fiord
title_sort ice-ocean interactions in milne fiord
publisher University of British Columbia
publishDate 2016
url http://hdl.handle.net/2429/59051
long_lat ENVELOPE(-81.747,-81.747,82.736,82.736)
ENVELOPE(-81.447,-81.447,82.636,82.636)
ENVELOPE(-79.997,-79.997,82.402,82.402)
geographic Arctic
Ellesmere Island
Milne Ice Shelf
Milne Fiord
Milne Glacier
geographic_facet Arctic
Ellesmere Island
Milne Ice Shelf
Milne Fiord
Milne Glacier
genre Arctic
Ellesmere Island
Ice Shelf
Ice Shelves
Milne Fiord
Milne Ice Shelf
genre_facet Arctic
Ellesmere Island
Ice Shelf
Ice Shelves
Milne Fiord
Milne Ice Shelf
op_rights Attribution-NonCommercial-NoDerivatives 4.0 International
http://creativecommons.org/licenses/by-nc-nd/4.0/
op_rightsnorm CC-BY-NC-ND
_version_ 1766347555537420288

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