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dc.contributor.authorDing, Xiaoling
dc.date.accessioned2018-08-08T19:20:24Z
dc.date.available2018-08-08T19:20:24Z
dc.date.issued1998
dc.identifier.urihttp://hdl.handle.net/11122/9521
dc.descriptionDissertation (Ph.D.) University of Alaska Fairbanks, 1998
dc.description.abstractContinental margin sediments provide a historical record of the sources and fate of organic matter (OM) originating both from the continents and from primary productivity in the overlying water column. However, since this record can be altered by microbial decomposition within the sediment, the history cannot be interpreted without understanding how decomposition can affect OM composition. Also, the margins accumulate much of the OM buried in ocean sediments; hence, knowledge of processes influencing preservation of OM in these sediments is essential to understanding the global carbon cycle. OM preservation was examined using two approaches. First, I studied sediments in the northeastern Gulf of Alaska to determine sources of OM and temporal changes in carbon accumulation. A large amount of OM, 45--70 x 104 tons/yr, accumulated in this region, about 50% from terrestrial sources. Most of the sediment cores showed little evidence of change in TOC, TN, or C and N stable isotope compositions due to decomposition within the sediment. Second, I investigated the processes that control OM preservation, focusing on the role of the OM adsorption to mineral surfaces. Because proteins are major constituents of sedimentary OM, I examined factors controlling their adsorption, decomposition, and preservation. Three hydrophilic proteins were strongly adsorbed by two clay minerals, an iron oxide, sub-oxic sediments from Resurrection Bay (RB), Alaska, and anoxic sediments from Skan Bay (SB), Alaska. The partition coefficients were large enough to lead to their preservation provided that the proteins did not decompose while adsorbed. Generally, adsorption of proteins to solid phases decreased decomposition rates, suggesting that adsorption is important in protecting these compounds from microbial attack. Greater protein decomposition rates were found in SB than in RB sediments, indicating that anoxia did not inhibit protein biodegradation. Naturally-occurring adsorbed proteins were extracted from SB and RB sediments using a detergent solution. Most of these adsorbed proteins were small (<12 kDa), indicating that only the proteins adsorbed within the micropores of particle surfaces are preserved long-term.
dc.subjectBiogeochemistry
dc.subjectGeochemistry
dc.subjectBiological oceanography
dc.subjectEcology
dc.titleOrganic matter accumulation and preservation in Alaskan continental margin sediments
dc.typeDissertation
dc.type.degreephd
dc.identifier.departmentGraduate Program in Marine Science and Limnology
dc.contributor.chairHenrichs, Susan M.
refterms.dateFOA2020-03-06T01:46:00Z


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