Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice

Convective dynamics developing below growing sea ice are studied experimentally by freezing salt water from above in a quasi-two-dimensional Hele-Shaw cell. Observations of the convective processes are made with Schlieren and direct imaging systems, allowing visualization both under and within the g...

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Published in:Physical Review Fluids
Main Authors: Middleton, CA, Gopalakrishnan, SS, Berenstein, I, Knaepen, B, Tison, J-L, De Wit, A
Format: Article in Journal/Newspaper
Language:English
Published: American Physical Society (APS) 2022
Subjects:
Sea ice
Online Access:https://livrepository.liverpool.ac.uk/3156180/
https://doi.org/10.1103/physrevfluids.7.043503
https://livrepository.liverpool.ac.uk/3156180/1/Middleton_PhysRevFluidsSeaIceConvectionFinalSubmission.pdf
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spelling ftunivliverpool:oai:livrepository.liverpool.ac.uk:3156180 2024-09-15T18:35:19+00:00 Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice Middleton, CA Gopalakrishnan, SS Berenstein, I Knaepen, B Tison, J-L De Wit, A 2022 text https://livrepository.liverpool.ac.uk/3156180/ https://doi.org/10.1103/physrevfluids.7.043503 https://livrepository.liverpool.ac.uk/3156180/1/Middleton_PhysRevFluidsSeaIceConvectionFinalSubmission.pdf en eng American Physical Society (APS) https://livrepository.liverpool.ac.uk/3156180/1/Middleton_PhysRevFluidsSeaIceConvectionFinalSubmission.pdf Middleton, CA, Gopalakrishnan, SS, Berenstein, I, Knaepen, B, Tison, J-L and De Wit, A (2022) Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice. PHYSICAL REVIEW FLUIDS, 7 (4). 043503-. Article NonPeerReviewed 2022 ftunivliverpool https://doi.org/10.1103/physrevfluids.7.043503 2024-07-08T14:17:39Z Convective dynamics developing below growing sea ice are studied experimentally by freezing salt water from above in a quasi-two-dimensional Hele-Shaw cell. Observations of the convective processes are made with Schlieren and direct imaging systems, allowing visualization both under and within the growing ice. Buoyancy-driven flows are seen to develop under the ice layer via two different mechanisms: On one hand, brine diffuses out from the ice layer creating a denser boundary layer of enhanced salinity, which triggers boundary layer convection resulting in small-scale interfacial fingers. On the other hand, internal flow within brine drainage channels inside the ice is observed flushing out longer-scale convective streamers at given locations at the ice-water interface. Streamers descend in the bulk aqueous layer faster and for longer distances than fingers. Simulations confirm that, despite nonlinear interactions between fingers and streamers, the different speeds observed can be correlated to different density differences between the interfacial or internal rejection and the underlying bulk salt water. Estimates of relative mass fluxes through the interface by the two mechanisms suggest that, when streamers are active, the mass of salt rejected through the streamer pathway can be larger than the one expelled through the finger pathway. However, as fingers are maintained throughout the ice growth while the rejection from brine channels features an intermittent "on-off" behavior, there are certain periods of time when the mass flux of the two mechanisms is similar, but also some time intervals during which the flux due to interfacial short fingers becomes dominant. Article in Journal/Newspaper Sea ice The University of Liverpool Repository Physical Review Fluids 7 4
institution Open Polar
collection The University of Liverpool Repository
op_collection_id ftunivliverpool
language English
description Convective dynamics developing below growing sea ice are studied experimentally by freezing salt water from above in a quasi-two-dimensional Hele-Shaw cell. Observations of the convective processes are made with Schlieren and direct imaging systems, allowing visualization both under and within the growing ice. Buoyancy-driven flows are seen to develop under the ice layer via two different mechanisms: On one hand, brine diffuses out from the ice layer creating a denser boundary layer of enhanced salinity, which triggers boundary layer convection resulting in small-scale interfacial fingers. On the other hand, internal flow within brine drainage channels inside the ice is observed flushing out longer-scale convective streamers at given locations at the ice-water interface. Streamers descend in the bulk aqueous layer faster and for longer distances than fingers. Simulations confirm that, despite nonlinear interactions between fingers and streamers, the different speeds observed can be correlated to different density differences between the interfacial or internal rejection and the underlying bulk salt water. Estimates of relative mass fluxes through the interface by the two mechanisms suggest that, when streamers are active, the mass of salt rejected through the streamer pathway can be larger than the one expelled through the finger pathway. However, as fingers are maintained throughout the ice growth while the rejection from brine channels features an intermittent "on-off" behavior, there are certain periods of time when the mass flux of the two mechanisms is similar, but also some time intervals during which the flux due to interfacial short fingers becomes dominant.
format Article in Journal/Newspaper
author Middleton, CA
Gopalakrishnan, SS
Berenstein, I
Knaepen, B
Tison, J-L
De Wit, A
spellingShingle Middleton, CA
Gopalakrishnan, SS
Berenstein, I
Knaepen, B
Tison, J-L
De Wit, A
Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
author_facet Middleton, CA
Gopalakrishnan, SS
Berenstein, I
Knaepen, B
Tison, J-L
De Wit, A
author_sort Middleton, CA
title Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
title_short Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
title_full Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
title_fullStr Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
title_full_unstemmed Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
title_sort relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice
publisher American Physical Society (APS)
publishDate 2022
url https://livrepository.liverpool.ac.uk/3156180/
https://doi.org/10.1103/physrevfluids.7.043503
https://livrepository.liverpool.ac.uk/3156180/1/Middleton_PhysRevFluidsSeaIceConvectionFinalSubmission.pdf
genre Sea ice
genre_facet Sea ice
op_relation https://livrepository.liverpool.ac.uk/3156180/1/Middleton_PhysRevFluidsSeaIceConvectionFinalSubmission.pdf
Middleton, CA, Gopalakrishnan, SS, Berenstein, I, Knaepen, B, Tison, J-L and De Wit, A (2022) Relative role of short interfacial fingers and long internally driven streamers in convective flows below growing sea ice. PHYSICAL REVIEW FLUIDS, 7 (4). 043503-.
op_doi https://doi.org/10.1103/physrevfluids.7.043503
container_title Physical Review Fluids
container_volume 7
container_issue 4
_version_ 1810478399687229440

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