Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies
This thesis explores turbulent ocean-to-ice heat transfer and consists of two main studies. The first is a laboratory experiment on the time evolution of an ice layer cooled from below and subjected to a turbulent shear flow of warm water from above. This experiment is motivated by observations of w...
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| Language: | English |
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Johns Hopkins University
2018
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| Online Access: | http://jhir.library.jhu.edu/handle/1774.2/59990 |
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ftjhuniv:oai:jscholarship.library.jhu.edu:1774.2/59990 2023-09-26T15:11:19+02:00 Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies Ramudu, Eshwan Gnanadesikan, Anand Meneveau, Charles Olson, Peter 2018-08 application/pdf application/octet-stream http://jhir.library.jhu.edu/handle/1774.2/59990 en_US eng Johns Hopkins University USA http://jhir.library.jhu.edu/handle/1774.2/59990 turbulent heat transfer ice-ocean interaction Thesis text 2018 ftjhuniv 2023-08-28T18:05:41Z This thesis explores turbulent ocean-to-ice heat transfer and consists of two main studies. The first is a laboratory experiment on the time evolution of an ice layer cooled from below and subjected to a turbulent shear flow of warm water from above. This experiment is motivated by observations of warm water intrusion into the ocean cavity under Antarctic ice shelves, accelerating the melting of their basal surfaces. Either partial transient melting or complete melting of the ice occurs in our experiments depending on the strength of the applied turbulent shear flow, which is represented in terms of its Reynolds number $\Rey$. The ice consequently reforms at a rate independent of $\Rey$. A one-dimensional model for the evolution of the ice thickness is derived from the experimental results. Applying our model to field measurements at a site under the Antarctic Pine Island Glacier ice shelf yields a predicted melt rate that exceeds present-day observations. Arctic sea ice is also rapidly declining. In the second study, we use large eddy simulation (LES) to investigate numerically the turbulent entrainment of heat from the mixed layer, a mechanism that is possibly partly responsible for the observed sea ice loss. We model the Arctic Ocean's Canada Basin, which features a perennial anomalously warm Pacific Summer Water (PSW) layer at the base of the mixed layer and a summertime Near-Surface Temperature Maximum (NSTM) within the mixed layer, trapping heat from solar radiation. The ice drift velocity and initial temperature profiles are varied in our simulations. The results show that the presence of the NSTM enhances heat entrainment from the mixed layer. Additionally there is no PSW heat entrained under the parameter space considered. We propose a scaling law for the ocean-to-ice heat flux, which depends on the initial NSTM temperature anomaly and the ice-drift velocity. In an extension of this LES study, we investigate, the effect of varying the ice basal surface roughness $z_0$ over three orders of magnitude, all ... Thesis Antarc* Antarctic Arctic canada basin glacier* Ice Shelf Ice Shelves Pine Island Glacier Sea ice Johns Hopkins University, Baltimore: JScholarship Antarctic Arctic Canada Pacific Pine Island Glacier ENVELOPE(-101.000,-101.000,-75.000,-75.000) The Antarctic |
| institution |
Open Polar |
| collection |
Johns Hopkins University, Baltimore: JScholarship |
| op_collection_id |
ftjhuniv |
| language |
English |
| topic |
turbulent heat transfer ice-ocean interaction |
| spellingShingle |
turbulent heat transfer ice-ocean interaction Ramudu, Eshwan Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies |
| topic_facet |
turbulent heat transfer ice-ocean interaction |
| description |
This thesis explores turbulent ocean-to-ice heat transfer and consists of two main studies. The first is a laboratory experiment on the time evolution of an ice layer cooled from below and subjected to a turbulent shear flow of warm water from above. This experiment is motivated by observations of warm water intrusion into the ocean cavity under Antarctic ice shelves, accelerating the melting of their basal surfaces. Either partial transient melting or complete melting of the ice occurs in our experiments depending on the strength of the applied turbulent shear flow, which is represented in terms of its Reynolds number $\Rey$. The ice consequently reforms at a rate independent of $\Rey$. A one-dimensional model for the evolution of the ice thickness is derived from the experimental results. Applying our model to field measurements at a site under the Antarctic Pine Island Glacier ice shelf yields a predicted melt rate that exceeds present-day observations. Arctic sea ice is also rapidly declining. In the second study, we use large eddy simulation (LES) to investigate numerically the turbulent entrainment of heat from the mixed layer, a mechanism that is possibly partly responsible for the observed sea ice loss. We model the Arctic Ocean's Canada Basin, which features a perennial anomalously warm Pacific Summer Water (PSW) layer at the base of the mixed layer and a summertime Near-Surface Temperature Maximum (NSTM) within the mixed layer, trapping heat from solar radiation. The ice drift velocity and initial temperature profiles are varied in our simulations. The results show that the presence of the NSTM enhances heat entrainment from the mixed layer. Additionally there is no PSW heat entrained under the parameter space considered. We propose a scaling law for the ocean-to-ice heat flux, which depends on the initial NSTM temperature anomaly and the ice-drift velocity. In an extension of this LES study, we investigate, the effect of varying the ice basal surface roughness $z_0$ over three orders of magnitude, all ... |
| author2 |
Gnanadesikan, Anand Meneveau, Charles Olson, Peter |
| format |
Thesis |
| author |
Ramudu, Eshwan |
| author_facet |
Ramudu, Eshwan |
| author_sort |
Ramudu, Eshwan |
| title |
Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies |
| title_short |
Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies |
| title_full |
Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies |
| title_fullStr |
Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies |
| title_full_unstemmed |
Turbulent ocean-to-ice heat transfer: Laboratory and numerical studies |
| title_sort |
turbulent ocean-to-ice heat transfer: laboratory and numerical studies |
| publisher |
Johns Hopkins University |
| publishDate |
2018 |
| url |
http://jhir.library.jhu.edu/handle/1774.2/59990 |
| long_lat |
ENVELOPE(-101.000,-101.000,-75.000,-75.000) |
| geographic |
Antarctic Arctic Canada Pacific Pine Island Glacier The Antarctic |
| geographic_facet |
Antarctic Arctic Canada Pacific Pine Island Glacier The Antarctic |
| genre |
Antarc* Antarctic Arctic canada basin glacier* Ice Shelf Ice Shelves Pine Island Glacier Sea ice |
| genre_facet |
Antarc* Antarctic Arctic canada basin glacier* Ice Shelf Ice Shelves Pine Island Glacier Sea ice |
| op_relation |
http://jhir.library.jhu.edu/handle/1774.2/59990 |
| _version_ |
1778131370810277888 |