Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean

Source-driven ocean currents that flow over topographic sills are important initiation sites for the abyssal component of the thermohaline circulation. These overflows exhibit vigorous space and time variability over many scales as they progress from a predominately gravity-driven downslope flow to...

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Bibliographic Details
Published in:Journal of Fluid Mechanics
Main Author: SWATERS, GORDON E.
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press (CUP) 2009
Subjects:
Mechanical Engineering
Mechanics of Materials
Condensed Matter Physics
Denmark Strait
Online Access:http://dx.doi.org/10.1017/s0022112008005673
https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S0022112008005673
id crcambridgeupr:10.1017/s0022112008005673
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spelling crcambridgeupr:10.1017/s0022112008005673 2024-03-03T08:43:52+00:00 Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean SWATERS, GORDON E. 2009 http://dx.doi.org/10.1017/s0022112008005673 https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S0022112008005673 en eng Cambridge University Press (CUP) https://www.cambridge.org/core/terms Journal of Fluid Mechanics volume 626, page 33-66 ISSN 0022-1120 1469-7645 Mechanical Engineering Mechanics of Materials Condensed Matter Physics journal-article 2009 crcambridgeupr https://doi.org/10.1017/s0022112008005673 2024-02-08T08:42:58Z Source-driven ocean currents that flow over topographic sills are important initiation sites for the abyssal component of the thermohaline circulation. These overflows exhibit vigorous space and time variability over many scales as they progress from a predominately gravity-driven downslope flow to a geostrophic along-slope current. Observations show that in the immediate vicinity of a sill, grounded abyssal ocean overflows can possess current speeds greater than the local long internal gravity wave speed with bottom friction and downslope gravitational acceleration dominating the flow evolution. It is shown that these dynamics lead to the mixed frictionally induced and Kelvin–Helmholtz instability of grounded abyssal overflows. Within the overflow, the linearized instabilities correspond to bottom-intensified baroclinic roll waves, and in the overlying water column amplifying internal gravity waves are generated. The stability characteristics are described as functions of the bottom drag coefficient and slope, Froude, bulk Richardson and Reynolds numbers associated with the overflow and the fractional thickness of the abyssal current compared to the mean depth of the overlying water column. The marginal stability boundary and the boundary separating the parameter regimes in which the most unstable mode has a finite or infinite wavenumber are determined. When it exists, the high-wavenumber cutoff is obtained. Conditions for the possible development of an ultraviolet catastrophe are determined. In the infinite-Reynolds-number limit, an exact solution is obtained which fully includes the effects of mean depth variations in the overlying water column associated with a sloping bottom. For parameter values characteristic of the Denmark Strait overflow, the most unstable mode has a wavelength of about 19 km, a geostationary period of about 14 hours, an e-folding amplification time of about 2 hours and a downslope phase speed of about 74 cm s −1 . Article in Journal/Newspaper Denmark Strait Cambridge University Press Journal of Fluid Mechanics 626 33 66
institution Open Polar
collection Cambridge University Press
op_collection_id crcambridgeupr
language English
topic Mechanical Engineering
Mechanics of Materials
Condensed Matter Physics
spellingShingle Mechanical Engineering
Mechanics of Materials
Condensed Matter Physics
SWATERS, GORDON E.
Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean
topic_facet Mechanical Engineering
Mechanics of Materials
Condensed Matter Physics
description Source-driven ocean currents that flow over topographic sills are important initiation sites for the abyssal component of the thermohaline circulation. These overflows exhibit vigorous space and time variability over many scales as they progress from a predominately gravity-driven downslope flow to a geostrophic along-slope current. Observations show that in the immediate vicinity of a sill, grounded abyssal ocean overflows can possess current speeds greater than the local long internal gravity wave speed with bottom friction and downslope gravitational acceleration dominating the flow evolution. It is shown that these dynamics lead to the mixed frictionally induced and Kelvin–Helmholtz instability of grounded abyssal overflows. Within the overflow, the linearized instabilities correspond to bottom-intensified baroclinic roll waves, and in the overlying water column amplifying internal gravity waves are generated. The stability characteristics are described as functions of the bottom drag coefficient and slope, Froude, bulk Richardson and Reynolds numbers associated with the overflow and the fractional thickness of the abyssal current compared to the mean depth of the overlying water column. The marginal stability boundary and the boundary separating the parameter regimes in which the most unstable mode has a finite or infinite wavenumber are determined. When it exists, the high-wavenumber cutoff is obtained. Conditions for the possible development of an ultraviolet catastrophe are determined. In the infinite-Reynolds-number limit, an exact solution is obtained which fully includes the effects of mean depth variations in the overlying water column associated with a sloping bottom. For parameter values characteristic of the Denmark Strait overflow, the most unstable mode has a wavelength of about 19 km, a geostationary period of about 14 hours, an e-folding amplification time of about 2 hours and a downslope phase speed of about 74 cm s −1 .
format Article in Journal/Newspaper
author SWATERS, GORDON E.
author_facet SWATERS, GORDON E.
author_sort SWATERS, GORDON E.
title Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean
title_short Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean
title_full Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean
title_fullStr Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean
title_full_unstemmed Mixed bottom-friction–Kelvin–Helmholtz destabilization of source-driven abyssal overflows in the ocean
title_sort mixed bottom-friction–kelvin–helmholtz destabilization of source-driven abyssal overflows in the ocean
publisher Cambridge University Press (CUP)
publishDate 2009
url http://dx.doi.org/10.1017/s0022112008005673
https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S0022112008005673
genre Denmark Strait
genre_facet Denmark Strait
op_source Journal of Fluid Mechanics
volume 626, page 33-66
ISSN 0022-1120 1469-7645
op_rights https://www.cambridge.org/core/terms
op_doi https://doi.org/10.1017/s0022112008005673
container_title Journal of Fluid Mechanics
container_volume 626
container_start_page 33
op_container_end_page 66
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