Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability
Dissolved oxygen (DO) is essential for marine life and biogeochemical cycling. To a first order approximation, DO is determined by the competition between ocean ventilation and biological productivity. Approximately 21% of the atmospheric gases is oxygen, and the waters at the ocean surface are enri...
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Georgia Institute of Technology
2021
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ftgeorgiatech:oai:repository.gatech.edu:1853/64575 2024-06-02T08:09:59+00:00 Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability Sun, Daoxun Ito, Takamitsu Bracco, Annalisa Di Lorenzo, Emanuele He, Jie Deutsch, Curtis Earth and Atmospheric Sciences 2021-06-10T13:51:17Z application/pdf http://hdl.handle.net/1853/64575 en_US eng Georgia Institute of Technology http://hdl.handle.net/1853/64575 oxygen exchange deep convection bubble injection compensation oxygen to ocean heat content ratio Text Dissertation 2021 ftgeorgiatech 2024-05-06T11:33:10Z Dissolved oxygen (DO) is essential for marine life and biogeochemical cycling. To a first order approximation, DO is determined by the competition between ocean ventilation and biological productivity. Approximately 21% of the atmospheric gases is oxygen, and the waters at the ocean surface are enriched in oxygen. Ventilation occurs through a suite of physical processes that brings the DO-rich surface waters into the interior ocean. This dissertation combines two works that closely examine the ventilation of oxygen in the region of deep water formation, and explore the relationship between air-sea oxygen flux and surface forcing aiming at deepening our understanding of the processes that regulate he DO inventory. Through these analyses we develop a framework to understand the oxygen to ocean heat content (O2-OHC) ratio in the ocean interior. Both works focus on the Labrador Sea and include a theoretical development and its validation using a suite of numerical sensitivity experiments. The first work leads to two main conclusions. 1) Both the duration and the intensity of the winter-time cooling are important to the total O2 uptake for a convective event. Stronger cooling leads to deeper convection and brings oxygen into deeper depths. Longer duration of the cooling period increases the total amount of oxygen uptake over the convective season. 2) The bubble-mediated influx of oxygen can increase oxygen uptake, but part of the contribution is compensated by the weakening the diffusive influx because the air-sea disequilibrium of oxygen is shifted towards supersaturation. The degree of compensation between the diffusive and bubble-mediated gas exchange depends on the relative strength of oceanic vertical mixing and the gas transfer velocity. Strong convective mixing reduces the degree of compensation so that the two components of gas exchange together drive exceptionally strong oceanic oxygen uptake. A numerical model with idealized domain and non-hydrostatic dynamics is used to test the hypotheses in this work. ... Doctoral or Postdoctoral Thesis Labrador Sea Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech |
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Open Polar |
collection |
Georgia Institute of Technology: SMARTech - Scholarly Materials and Research at Georgia Tech |
op_collection_id |
ftgeorgiatech |
language |
English |
topic |
oxygen exchange deep convection bubble injection compensation oxygen to ocean heat content ratio |
spellingShingle |
oxygen exchange deep convection bubble injection compensation oxygen to ocean heat content ratio Sun, Daoxun Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability |
topic_facet |
oxygen exchange deep convection bubble injection compensation oxygen to ocean heat content ratio |
description |
Dissolved oxygen (DO) is essential for marine life and biogeochemical cycling. To a first order approximation, DO is determined by the competition between ocean ventilation and biological productivity. Approximately 21% of the atmospheric gases is oxygen, and the waters at the ocean surface are enriched in oxygen. Ventilation occurs through a suite of physical processes that brings the DO-rich surface waters into the interior ocean. This dissertation combines two works that closely examine the ventilation of oxygen in the region of deep water formation, and explore the relationship between air-sea oxygen flux and surface forcing aiming at deepening our understanding of the processes that regulate he DO inventory. Through these analyses we develop a framework to understand the oxygen to ocean heat content (O2-OHC) ratio in the ocean interior. Both works focus on the Labrador Sea and include a theoretical development and its validation using a suite of numerical sensitivity experiments. The first work leads to two main conclusions. 1) Both the duration and the intensity of the winter-time cooling are important to the total O2 uptake for a convective event. Stronger cooling leads to deeper convection and brings oxygen into deeper depths. Longer duration of the cooling period increases the total amount of oxygen uptake over the convective season. 2) The bubble-mediated influx of oxygen can increase oxygen uptake, but part of the contribution is compensated by the weakening the diffusive influx because the air-sea disequilibrium of oxygen is shifted towards supersaturation. The degree of compensation between the diffusive and bubble-mediated gas exchange depends on the relative strength of oceanic vertical mixing and the gas transfer velocity. Strong convective mixing reduces the degree of compensation so that the two components of gas exchange together drive exceptionally strong oceanic oxygen uptake. A numerical model with idealized domain and non-hydrostatic dynamics is used to test the hypotheses in this work. ... |
author2 |
Ito, Takamitsu Bracco, Annalisa Di Lorenzo, Emanuele He, Jie Deutsch, Curtis Earth and Atmospheric Sciences |
format |
Doctoral or Postdoctoral Thesis |
author |
Sun, Daoxun |
author_facet |
Sun, Daoxun |
author_sort |
Sun, Daoxun |
title |
Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability |
title_short |
Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability |
title_full |
Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability |
title_fullStr |
Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability |
title_full_unstemmed |
Oxygen uptake and vertical transport during deep convection events in the Labrador Sea and its interannual variability |
title_sort |
oxygen uptake and vertical transport during deep convection events in the labrador sea and its interannual variability |
publisher |
Georgia Institute of Technology |
publishDate |
2021 |
url |
http://hdl.handle.net/1853/64575 |
genre |
Labrador Sea |
genre_facet |
Labrador Sea |
op_relation |
http://hdl.handle.net/1853/64575 |
_version_ |
1800755773896130560 |