Geothermal heating, diapycnal mixing and the abyssal circulation

The dynamical role of geothermal heating in abyssal circulation is reconsidered using three independent arguments. First, we show that a uniform geothermal heat flux close to the observed average (86.4 mW m −2 ) supplies as much heat to near-bottom water as a diapycnal mixing rate of ~10 −4 m 2 s −1...

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Published in:Ocean Science
Main Authors: Emile-Geay, J., Madec, G.
Format: Text
Language:English
Published: 2018
Subjects:
Pacific
Southern Ocean
Online Access:https://doi.org/10.5194/os-5-203-2009
https://os.copernicus.org/articles/5/203/2009/
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spelling ftcopernicus:oai:publications.copernicus.org:os6966 2023-05-15T18:26:03+02:00 Geothermal heating, diapycnal mixing and the abyssal circulation Emile-Geay, J. Madec, G. 2018-01-15 application/pdf https://doi.org/10.5194/os-5-203-2009 https://os.copernicus.org/articles/5/203/2009/ eng eng doi:10.5194/os-5-203-2009 https://os.copernicus.org/articles/5/203/2009/ eISSN: 1812-0792 Text 2018 ftcopernicus https://doi.org/10.5194/os-5-203-2009 2020-07-20T16:26:39Z The dynamical role of geothermal heating in abyssal circulation is reconsidered using three independent arguments. First, we show that a uniform geothermal heat flux close to the observed average (86.4 mW m −2 ) supplies as much heat to near-bottom water as a diapycnal mixing rate of ~10 −4 m 2 s −1 – the canonical value thought to be responsible for the magnitude of the present-day abyssal circulation. This parity raises the possibility that geothermal heating could have a dynamical impact of the same order. Second, we estimate the magnitude of geothermally-induced circulation with the density-binning method (Walin, 1982), applied to the observed thermohaline structure of Levitus (1998). The method also allows to investigate the effect of realistic spatial variations of the flux obtained from heatflow measurements and classical theories of lithospheric cooling. It is found that a uniform heatflow forces a transformation of ~6 Sv at σ 4 =45.90, which is of the same order as current best estimates of AABW circulation. This transformation can be thought of as the geothermal circulation in the absence of mixing and is very similar for a realistic heatflow, albeit shifted towards slightly lighter density classes. Third, we use a general ocean circulation model in global configuration to perform three sets of experiments: (1) a thermally homogenous abyssal ocean with and without uniform geothermal heating; (2) a more stratified abyssal ocean subject to (i) no geothermal heating, (ii) a constant heat flux of 86.4 mW m −2 , (iii) a realistic, spatially varying heat flux of identical global average; (3) experiments (i) and (iii) with enhanced vertical mixing at depth. Geothermal heating and diapycnal mixing are found to interact non-linearly through the density field, with geothermal heating eroding the deep stratification supporting a downward diffusive flux, while diapycnal mixing acts to map near-surface temperature gradients onto the bottom, thereby altering the density structure that supports a geothermal circulation. For strong vertical mixing rates, geothermal heating enhances the AABW cell by about 15% (2.5 Sv) and heats up the last 2000 m by ~0.15°C, reaching a maximum of by 0.3°C in the deep North Pacific. Prescribing a realistic spatial distribution of the heat flux acts to enhance this temperature rise at mid-depth and reduce it at great depth, producing a more modest increase in overturning than in the uniform case. In all cases, however, poleward heat transport increases by ~10% in the Southern Ocean. The three approaches converge to the conclusion that geothermal heating is an important actor of abyssal dynamics, and should no longer be neglected in oceanographic studies. Text Southern Ocean Copernicus Publications: E-Journals Pacific Southern Ocean Ocean Science 5 2 203 217
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description The dynamical role of geothermal heating in abyssal circulation is reconsidered using three independent arguments. First, we show that a uniform geothermal heat flux close to the observed average (86.4 mW m −2 ) supplies as much heat to near-bottom water as a diapycnal mixing rate of ~10 −4 m 2 s −1 – the canonical value thought to be responsible for the magnitude of the present-day abyssal circulation. This parity raises the possibility that geothermal heating could have a dynamical impact of the same order. Second, we estimate the magnitude of geothermally-induced circulation with the density-binning method (Walin, 1982), applied to the observed thermohaline structure of Levitus (1998). The method also allows to investigate the effect of realistic spatial variations of the flux obtained from heatflow measurements and classical theories of lithospheric cooling. It is found that a uniform heatflow forces a transformation of ~6 Sv at σ 4 =45.90, which is of the same order as current best estimates of AABW circulation. This transformation can be thought of as the geothermal circulation in the absence of mixing and is very similar for a realistic heatflow, albeit shifted towards slightly lighter density classes. Third, we use a general ocean circulation model in global configuration to perform three sets of experiments: (1) a thermally homogenous abyssal ocean with and without uniform geothermal heating; (2) a more stratified abyssal ocean subject to (i) no geothermal heating, (ii) a constant heat flux of 86.4 mW m −2 , (iii) a realistic, spatially varying heat flux of identical global average; (3) experiments (i) and (iii) with enhanced vertical mixing at depth. Geothermal heating and diapycnal mixing are found to interact non-linearly through the density field, with geothermal heating eroding the deep stratification supporting a downward diffusive flux, while diapycnal mixing acts to map near-surface temperature gradients onto the bottom, thereby altering the density structure that supports a geothermal circulation. For strong vertical mixing rates, geothermal heating enhances the AABW cell by about 15% (2.5 Sv) and heats up the last 2000 m by ~0.15°C, reaching a maximum of by 0.3°C in the deep North Pacific. Prescribing a realistic spatial distribution of the heat flux acts to enhance this temperature rise at mid-depth and reduce it at great depth, producing a more modest increase in overturning than in the uniform case. In all cases, however, poleward heat transport increases by ~10% in the Southern Ocean. The three approaches converge to the conclusion that geothermal heating is an important actor of abyssal dynamics, and should no longer be neglected in oceanographic studies.
format Text
author Emile-Geay, J.
Madec, G.
spellingShingle Emile-Geay, J.
Madec, G.
Geothermal heating, diapycnal mixing and the abyssal circulation
author_facet Emile-Geay, J.
Madec, G.
author_sort Emile-Geay, J.
title Geothermal heating, diapycnal mixing and the abyssal circulation
title_short Geothermal heating, diapycnal mixing and the abyssal circulation
title_full Geothermal heating, diapycnal mixing and the abyssal circulation
title_fullStr Geothermal heating, diapycnal mixing and the abyssal circulation
title_full_unstemmed Geothermal heating, diapycnal mixing and the abyssal circulation
title_sort geothermal heating, diapycnal mixing and the abyssal circulation
publishDate 2018
url https://doi.org/10.5194/os-5-203-2009
https://os.copernicus.org/articles/5/203/2009/
geographic Pacific
Southern Ocean
geographic_facet Pacific
Southern Ocean
genre Southern Ocean
genre_facet Southern Ocean
op_source eISSN: 1812-0792
op_relation doi:10.5194/os-5-203-2009
https://os.copernicus.org/articles/5/203/2009/
op_doi https://doi.org/10.5194/os-5-203-2009
container_title Ocean Science
container_volume 5
container_issue 2
container_start_page 203
op_container_end_page 217
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