Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean

The Amazon River discharges low-salinity, low-carbon water into the western tropical North Atlantic (WTNA), where the resultant plume stretches thousands of kilometers offshore and creates a sink for atmospheric carbon dioxide (CO2). The presence of a carbon sink in tropical oceans is noteworthy bec...

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Bibliographic Details
Main Author: Cooley, Sarah Rebecca
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: uga 2006
Subjects:
Ocean carbon cycle
CO2
atmospheric CO2 sink
Amazon River
Tropical
Atlantic Ocean
Burd
North Atlantic
Online Access:http://hdl.handle.net/10724/23337
http://purl.galileo.usg.edu/uga_etd/cooley_sarah_r_200608_phd
id ftunivgeorgia:oai:athenaeum.libs.uga.edu:10724/23337
record_format openpolar
spelling ftunivgeorgia:oai:athenaeum.libs.uga.edu:10724/23337 2023-05-15T17:32:36+02:00 Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean Cooley, Sarah Rebecca 2006-08 http://hdl.handle.net/10724/23337 http://purl.galileo.usg.edu/uga_etd/cooley_sarah_r_200608_phd eng eng uga cooley_sarah_r_200608_phd http://purl.galileo.usg.edu/uga_etd/cooley_sarah_r_200608_phd http://hdl.handle.net/10724/23337 public Ocean carbon cycle CO2 atmospheric CO2 sink Amazon River Tropical Atlantic Ocean Dissertation 2006 ftunivgeorgia 2020-09-23T12:12:36Z The Amazon River discharges low-salinity, low-carbon water into the western tropical North Atlantic (WTNA), where the resultant plume stretches thousands of kilometers offshore and creates a sink for atmospheric carbon dioxide (CO2). The presence of a carbon sink in tropical oceans is noteworthy because tropical waters typically release CO2 to the atmosphere; the relative contributions of physical mixing and biological production must be understood, however, before the potential for changes in the magnitude of the sink can be determined. Biological production and subsequent export is the only process in tropical waters that can lead to a long-term sequestration of atmospheric carbon. This dissertation combines observational data and modeling studies to quantify the major inorganic carbon fluxes through the WTNA, so that the Amazon plume-related carbon sink can be understood mechanistically. I first distinguish between physical and biological effects on CO2 in the offshore plume using observational data, and find that biological drawdown is greatest in association with diazotroph-containing diatoms. Then I determine the relative importance of seasonality in plume supply or processing on the offshore plume-related atmospheric carbon sink, and conclude that although supply of inorganic carbon to the Amazon plume does vary through the year, offshore biological processing year-round has the greatest capacity to alter the magnitude of the sink, although its impact may vary depending on meteorological control. Finally, I examine the role of mixing at the edge of the plume, to understand the ultimate fate of the plume-related deficit in inorganic carbon. Vertical mixing is too small to completely eliminate plume-related inorganic carbon deficits, and horizontal advection and mixing must occur to bring plume water to nonplume conditions in the observed lifetime of the plume. As a result, the Amazon River plume-associated deficit may reduce WTNA inorganic carbon efflux beyond the borders of its low-salinity plume. PhD Marine Sciences Marine Sciences Patricia L. Yager Patricia L. Yager Brian Binder Wei-Jun Cai Adrian Burd Victoria Coles Doctoral or Postdoctoral Thesis North Atlantic University of Georgia: Athenaeum@UGA Burd ENVELOPE(-57.150,-57.150,-63.650,-63.650)
institution Open Polar
collection University of Georgia: Athenaeum@UGA
op_collection_id ftunivgeorgia
language English
topic Ocean carbon cycle
CO2
atmospheric CO2 sink
Amazon River
Tropical
Atlantic Ocean
spellingShingle Ocean carbon cycle
CO2
atmospheric CO2 sink
Amazon River
Tropical
Atlantic Ocean
Cooley, Sarah Rebecca
Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean
topic_facet Ocean carbon cycle
CO2
atmospheric CO2 sink
Amazon River
Tropical
Atlantic Ocean
description The Amazon River discharges low-salinity, low-carbon water into the western tropical North Atlantic (WTNA), where the resultant plume stretches thousands of kilometers offshore and creates a sink for atmospheric carbon dioxide (CO2). The presence of a carbon sink in tropical oceans is noteworthy because tropical waters typically release CO2 to the atmosphere; the relative contributions of physical mixing and biological production must be understood, however, before the potential for changes in the magnitude of the sink can be determined. Biological production and subsequent export is the only process in tropical waters that can lead to a long-term sequestration of atmospheric carbon. This dissertation combines observational data and modeling studies to quantify the major inorganic carbon fluxes through the WTNA, so that the Amazon plume-related carbon sink can be understood mechanistically. I first distinguish between physical and biological effects on CO2 in the offshore plume using observational data, and find that biological drawdown is greatest in association with diazotroph-containing diatoms. Then I determine the relative importance of seasonality in plume supply or processing on the offshore plume-related atmospheric carbon sink, and conclude that although supply of inorganic carbon to the Amazon plume does vary through the year, offshore biological processing year-round has the greatest capacity to alter the magnitude of the sink, although its impact may vary depending on meteorological control. Finally, I examine the role of mixing at the edge of the plume, to understand the ultimate fate of the plume-related deficit in inorganic carbon. Vertical mixing is too small to completely eliminate plume-related inorganic carbon deficits, and horizontal advection and mixing must occur to bring plume water to nonplume conditions in the observed lifetime of the plume. As a result, the Amazon River plume-associated deficit may reduce WTNA inorganic carbon efflux beyond the borders of its low-salinity plume. PhD Marine Sciences Marine Sciences Patricia L. Yager Patricia L. Yager Brian Binder Wei-Jun Cai Adrian Burd Victoria Coles
format Doctoral or Postdoctoral Thesis
author Cooley, Sarah Rebecca
author_facet Cooley, Sarah Rebecca
author_sort Cooley, Sarah Rebecca
title Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean
title_short Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean
title_full Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean
title_fullStr Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean
title_full_unstemmed Dissolved inorganic carbon cycling in the offshore Amazon River plume and the western tropical North Atlantic ocean
title_sort dissolved inorganic carbon cycling in the offshore amazon river plume and the western tropical north atlantic ocean
publisher uga
publishDate 2006
url http://hdl.handle.net/10724/23337
http://purl.galileo.usg.edu/uga_etd/cooley_sarah_r_200608_phd
long_lat ENVELOPE(-57.150,-57.150,-63.650,-63.650)
geographic Burd
geographic_facet Burd
genre North Atlantic
genre_facet North Atlantic
op_relation cooley_sarah_r_200608_phd
http://purl.galileo.usg.edu/uga_etd/cooley_sarah_r_200608_phd
http://hdl.handle.net/10724/23337
op_rights public
_version_ 1766130795736465408

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