Distribution and Trend of Wind Power Input to Near‐Inertial Motions in the Southern Ocean

Wind power input to near‐inertial motions is an important energy source for generating diapycnal mixing in the ocean. However, the distribution and long‐term trend of this input over the Southern Ocean have yet to be quantified. In this study, we investigate the near‐inertial wind power input (WPIi)...

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Published in:Geophysical research letters 2023-09, Vol.50 (18), p.n/a
Main Authors: Qian, Jiangchao, Zhai, Xiaoming, Wang, Zhaomin, Jochum, Markus
Format: Article
Language:English
Subjects:
Amplification
Atmospheric circulation
Atmospheric data
Diapycnal mixing
Distribution
Energy sources
Inertial currents
Mesoscale phenomena
Ocean circulation
Ocean circulation models
Ocean currents
Ocean mixing
Ocean models
Oceans
Sea ice
Sea ice models
Skewed distributions
Turbulent mixing
Weather
Wind fluctuations
Wind power
Wind variations
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Wang, Zhaomin
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description Wind power input to near‐inertial motions is an important energy source for generating diapycnal mixing in the ocean. However, the distribution and long‐term trend of this input over the Southern Ocean have yet to be quantified. In this study, we investigate the near‐inertial wind power input (WPIi) to the Southern Ocean using a global eddy‐permitting coupled ocean‐sea ice model forced by a high‐resolution atmospheric reanalysis product. Our results reveal a zonally asymmetric distribution of WPIi in the Southern Ocean, with the strongest input in the South Indian Ocean and the weakest in the South Pacific. The integrated WPIi between 30°S and 60°S exhibits a significant positive trend over the past four decades due to the intensification of mesoscale weather systems. The surface mixed‐layer depth is found to modulate the spatial pattern and trend of WPIi by altering the surface near‐inertial currents. Plain Language Summary Wind fluctuations can excite surface ocean currents that oscillate at frequencies close to the inertial frequency. These near‐inertial motions play an important role in generating turbulent mixing in the ocean. However, the distribution and long‐term trend of wind power input to near‐inertial motions in the Southern Ocean remains unquantified. In this study, we investigate this wind power input using a global ocean circulation model driven by a high‐resolution atmospheric reanalysis data set. Our results reveal a pronounced zonal asymmetry in the distribution of near‐inertial wind power input in the Southern Ocean. Furthermore, this power input has increased significantly over the past four decades due to the intensification of mesoscale weather systems. Results from this study have important implications for understanding Southern Ocean mixing and circulation. Key Points Distribution of near‐inertial wind power input in the Southern Ocean is zonally asymmetric Near‐inertial wind power input in the Southern Ocean has increased significantly in recent decades This increase is primarily driven by the intensification of mesoscale weather systems
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However, the distribution and long‐term trend of this input over the Southern Ocean have yet to be quantified. In this study, we investigate the near‐inertial wind power input (WPIi) to the Southern Ocean using a global eddy‐permitting coupled ocean‐sea ice model forced by a high‐resolution atmospheric reanalysis product. Our results reveal a zonally asymmetric distribution of WPIi in the Southern Ocean, with the strongest input in the South Indian Ocean and the weakest in the South Pacific. The integrated WPIi between 30°S and 60°S exhibits a significant positive trend over the past four decades due to the intensification of mesoscale weather systems. The surface mixed‐layer depth is found to modulate the spatial pattern and trend of WPIi by altering the surface near‐inertial currents. Plain Language Summary Wind fluctuations can excite surface ocean currents that oscillate at frequencies close to the inertial frequency. These near‐inertial motions play an important role in generating turbulent mixing in the ocean. However, the distribution and long‐term trend of wind power input to near‐inertial motions in the Southern Ocean remains unquantified. In this study, we investigate this wind power input using a global ocean circulation model driven by a high‐resolution atmospheric reanalysis data set. Our results reveal a pronounced zonal asymmetry in the distribution of near‐inertial wind power input in the Southern Ocean. Furthermore, this power input has increased significantly over the past four decades due to the intensification of mesoscale weather systems. Results from this study have important implications for understanding Southern Ocean mixing and circulation. Key Points Distribution of near‐inertial wind power input in the Southern Ocean is zonally asymmetric Near‐inertial wind power input in the Southern Ocean has increased significantly in recent decades This increase is primarily driven by the intensification of mesoscale weather systems</description><identifier>ISSN: 0094-8276</identifier><identifier>EISSN: 1944-8007</identifier><identifier>DOI: 10.1029/2023GL105411</identifier><language>eng</language><publisher>Washington: John Wiley &amp; Sons, Inc</publisher><subject>Amplification ; Atmospheric circulation ; Atmospheric data ; Diapycnal mixing ; Distribution ; Energy sources ; Inertial currents ; Mesoscale phenomena ; Ocean circulation ; Ocean circulation models ; Ocean currents ; Ocean mixing ; Ocean models ; Oceans ; Sea ice ; Sea ice models ; Skewed distributions ; Turbulent mixing ; Weather ; Wind fluctuations ; Wind power ; Wind variations</subject><ispartof>Geophysical research letters, 2023-09, Vol.50 (18), p.n/a</ispartof><rights>2023. 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However, the distribution and long‐term trend of this input over the Southern Ocean have yet to be quantified. In this study, we investigate the near‐inertial wind power input (WPIi) to the Southern Ocean using a global eddy‐permitting coupled ocean‐sea ice model forced by a high‐resolution atmospheric reanalysis product. Our results reveal a zonally asymmetric distribution of WPIi in the Southern Ocean, with the strongest input in the South Indian Ocean and the weakest in the South Pacific. The integrated WPIi between 30°S and 60°S exhibits a significant positive trend over the past four decades due to the intensification of mesoscale weather systems. The surface mixed‐layer depth is found to modulate the spatial pattern and trend of WPIi by altering the surface near‐inertial currents. Plain Language Summary Wind fluctuations can excite surface ocean currents that oscillate at frequencies close to the inertial frequency. 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However, the distribution and long‐term trend of this input over the Southern Ocean have yet to be quantified. In this study, we investigate the near‐inertial wind power input (WPIi) to the Southern Ocean using a global eddy‐permitting coupled ocean‐sea ice model forced by a high‐resolution atmospheric reanalysis product. Our results reveal a zonally asymmetric distribution of WPIi in the Southern Ocean, with the strongest input in the South Indian Ocean and the weakest in the South Pacific. The integrated WPIi between 30°S and 60°S exhibits a significant positive trend over the past four decades due to the intensification of mesoscale weather systems. The surface mixed‐layer depth is found to modulate the spatial pattern and trend of WPIi by altering the surface near‐inertial currents. Plain Language Summary Wind fluctuations can excite surface ocean currents that oscillate at frequencies close to the inertial frequency. These near‐inertial motions play an important role in generating turbulent mixing in the ocean. However, the distribution and long‐term trend of wind power input to near‐inertial motions in the Southern Ocean remains unquantified. In this study, we investigate this wind power input using a global ocean circulation model driven by a high‐resolution atmospheric reanalysis data set. Our results reveal a pronounced zonal asymmetry in the distribution of near‐inertial wind power input in the Southern Ocean. Furthermore, this power input has increased significantly over the past four decades due to the intensification of mesoscale weather systems. Results from this study have important implications for understanding Southern Ocean mixing and circulation. Key Points Distribution of near‐inertial wind power input in the Southern Ocean is zonally asymmetric Near‐inertial wind power input in the Southern Ocean has increased significantly in recent decades This increase is primarily driven by the intensification of mesoscale weather systems</abstract><cop>Washington</cop><pub>John Wiley &amp; Sons, Inc</pub><doi>10.1029/2023GL105411</doi><tpages>9</tpages><orcidid>https://orcid.org/0000-0001-6357-2354</orcidid><oa>free_for_read</oa></addata></record>
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source Wiley-Blackwell AGU Digital Library; Wiley Online Library Open Access
subjects Amplification
Atmospheric circulation
Atmospheric data
Diapycnal mixing
Distribution
Energy sources
Inertial currents
Mesoscale phenomena
Ocean circulation
Ocean circulation models
Ocean currents
Ocean mixing
Ocean models
Oceans
Sea ice
Sea ice models
Skewed distributions
Turbulent mixing
Weather
Wind fluctuations
Wind power
Wind variations
title Distribution and Trend of Wind Power Input to Near‐Inertial Motions in the Southern Ocean
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