Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes

Methane (CH4) is second only to CO2 as a greenhouse gas and is produced in the terminal step of organic matter decomposition in anaerobic environments, including lake sediments. Given the widespread distribution of lakes in Arctic Alaska, CH4 emission from these lakes may significantly contribute to...

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Main Author: Lofton, Dendy D.
Other Authors: Whalen, Stephen Charles, 1952-;
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: University of North Carolina at Chapel Hill. Library 2012
Subjects:
Online Access:http://dc.lib.unc.edu/u?/etd,5660
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spelling ftuninorthcardc:oai:dc.lib.unc.edu:etd/5660 2023-05-15T14:48:41+02:00 Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes Lofton, Dendy D. Whalen, Stephen Charles, 1952-; 2012-08 1.29 MB http://dc.lib.unc.edu/u?/etd,5660 English eng University of North Carolina at Chapel Hill. Library University of North Carolina at Chapel Hill http://dc.lib.unc.edu/u?/etd,5660 Author The author has granted the University of North Carolina at Chapel Hill a limited, non-exclusive right to make this publication available to the public. The author retains all other rights. Dissertations Dissertation 2012 ftuninorthcardc 2013-11-17T00:23:34Z Methane (CH4) is second only to CO2 as a greenhouse gas and is produced in the terminal step of organic matter decomposition in anaerobic environments, including lake sediments. Given the widespread distribution of lakes in Arctic Alaska, CH4 emission from these lakes may significantly contribute to the atmospheric CH4 budget. Aerobic methane oxidizing bacteria consume CH4 diffusing from anaerobic zones of production, thereby modulating the flux of CH4 to the atmosphere. Multiple research efforts indicate a significant source strength for arctic environments in the atmospheric CH4 budget. Predicted climate induced alterations to the arctic landscape include increased organic matter loading from the terrestrial environment and increased temperature. These environmental changes can influence both rates of CH4 production and oxidation, possibly altering rates of CH4 exchange between shallow arctic lakes and the atmosphere. I assessed rates and controls on CH4 production and oxidation in two shallow arctic lakes to provide insight into the response of these two microbial groups to projected future climates. Rates of total methanogenesis and the fractional contribution of the acetoclastic pathway decreased with increasing depth below the sediment surface to 5 cm in both lakes. Substrate additions indicated substrate limitation to both methanogenic pathways (acetoclastic and hydrogenotrophic). Rates of total methanogenesis varied spatially in the horizontal dimension in one lake only. However, there was no consistent relationship between rates of methanogenesis and depth of the overlying water as labile organic matter in the shallow sediments are likely resuspended and deposited unevenly by wind action. Under extant conditions, rates of methanogenesis responded positively to increases in temperature, while rates of CH4 oxidation remained unchanged. The former were controlled by substrate x temperature interactions, while the latter were regulated strictly by substrate supply. Analysis of CH4 oxidation kinetics for water samples points to a community of CH4 oxidizing bacteria that is capable of oxidizing CH4 at concentrations far in excess of observed levels. Increases in organic matter supply and temperature under future climates will likely increase rates of methanogenesis, but the impact may be fully mitigated by the excessive capacity of the CH4-oxidizing community to process the added substrate. Doctoral or Postdoctoral Thesis Arctic Alaska University of North Carolina: UNC Digital Collections Arctic
institution Open Polar
collection University of North Carolina: UNC Digital Collections
op_collection_id ftuninorthcardc
language English
description Methane (CH4) is second only to CO2 as a greenhouse gas and is produced in the terminal step of organic matter decomposition in anaerobic environments, including lake sediments. Given the widespread distribution of lakes in Arctic Alaska, CH4 emission from these lakes may significantly contribute to the atmospheric CH4 budget. Aerobic methane oxidizing bacteria consume CH4 diffusing from anaerobic zones of production, thereby modulating the flux of CH4 to the atmosphere. Multiple research efforts indicate a significant source strength for arctic environments in the atmospheric CH4 budget. Predicted climate induced alterations to the arctic landscape include increased organic matter loading from the terrestrial environment and increased temperature. These environmental changes can influence both rates of CH4 production and oxidation, possibly altering rates of CH4 exchange between shallow arctic lakes and the atmosphere. I assessed rates and controls on CH4 production and oxidation in two shallow arctic lakes to provide insight into the response of these two microbial groups to projected future climates. Rates of total methanogenesis and the fractional contribution of the acetoclastic pathway decreased with increasing depth below the sediment surface to 5 cm in both lakes. Substrate additions indicated substrate limitation to both methanogenic pathways (acetoclastic and hydrogenotrophic). Rates of total methanogenesis varied spatially in the horizontal dimension in one lake only. However, there was no consistent relationship between rates of methanogenesis and depth of the overlying water as labile organic matter in the shallow sediments are likely resuspended and deposited unevenly by wind action. Under extant conditions, rates of methanogenesis responded positively to increases in temperature, while rates of CH4 oxidation remained unchanged. The former were controlled by substrate x temperature interactions, while the latter were regulated strictly by substrate supply. Analysis of CH4 oxidation kinetics for water samples points to a community of CH4 oxidizing bacteria that is capable of oxidizing CH4 at concentrations far in excess of observed levels. Increases in organic matter supply and temperature under future climates will likely increase rates of methanogenesis, but the impact may be fully mitigated by the excessive capacity of the CH4-oxidizing community to process the added substrate.
author2 Whalen, Stephen Charles, 1952-;
format Doctoral or Postdoctoral Thesis
author Lofton, Dendy D.
spellingShingle Lofton, Dendy D.
Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes
author_facet Lofton, Dendy D.
author_sort Lofton, Dendy D.
title Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes
title_short Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes
title_full Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes
title_fullStr Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes
title_full_unstemmed Factors Regulating Methane Production and Oxidation in Two Shallow Arctic Alaskan Lakes
title_sort factors regulating methane production and oxidation in two shallow arctic alaskan lakes
publisher University of North Carolina at Chapel Hill. Library
publishDate 2012
url http://dc.lib.unc.edu/u?/etd,5660
geographic Arctic
geographic_facet Arctic
genre Arctic
Alaska
genre_facet Arctic
Alaska
op_relation http://dc.lib.unc.edu/u?/etd,5660
op_rights Author
The author has granted the University of North Carolina at Chapel Hill a limited, non-exclusive right to make this publication available to the public. The author retains all other rights.
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