Francke, Alexander; Tsimosh, Olly; Tibby, John; Reid, Michael; Fletcher, Michael-Shawn; Tyler, Jonathan James

Author(s)

Francke, Alexander

Tsimosh, Olly

Tibby, John

Reid, Michael

Fletcher, Michael-Shawn

Tyler, Jonathan James

Publication Date

2023-01

Abstract

<p>A thorough understanding of controls over terrestrial sedimentary organic carbon characteristics in both the present and the past is pivotal to better understand atmospheric CO2 pathways into depositional sinks such as peats, swamps, and lakes. We explored the relationship between wetland sediment organic matter storage, climate (precipitation, temperature) and catchment vegetation data (catchment vegetation cover in percent" leaf carbon content in g/m2) by means of multivariate statistical analyses to investigate patterns of carbon deposition in modern wetlands and to provide a more robust framework for interpreting sediment bulk organic geochemistry as a proxy for past carbon cycling. Carbon and nitrogen elemental concentration and stable isotope composition were analyzed from sub-surface sediments at 18 wetlands in eastern Australia. The statistical analyses indicate that variability in geochemical organic matter data in wetland sediments is best explained by geographic differences in catchment vegetation cover and, by inference, the balance of terrestrial versus aquatic organic matter input to the sediment. TOC/TN of aquatic matter may be additionally driven toward higher (terrestrial) values by nitrogen limitation in the catchment and the lakes. These processes explain up to ∼40% of the total variance in the sediment geochemistry (redundancy analyses). Up to ∼10% of the total variance may be attributed to post-depositional processes and organic matter remineralization. The remaining ∼50% of total variance in the data may be attributed to local conditions across the sites, geochemical processes that were not captured in this study, or to the different timescales covered by the sediments at each site.</p>

Citation

Journal of Geophysical Research: Biogeosciences, 128(1), p. 1-17

ISSN

2169-8961

2169-8953

Link

https://hdl.handle.net/1959.11/57470

Publisher

Wiley-Blackwell Publishing, Inc

Rights

Attribution-NonCommercial 4.0 International

Title

Contemporary Controls on Terrestrial Carbon Characteristics in Temperate and Sub-Tropical Australian Wetlands

Type of document

Journal Article

Entity Type

Publication

Author(s)	Francke, Alexander Tsimosh, Olly Tibby, John Reid, Michael Fletcher, Michael-Shawn Tyler, Jonathan James
Publication Date	2023-01
Abstract	<p>A thorough understanding of controls over terrestrial sedimentary organic carbon characteristics in both the present and the past is pivotal to better understand atmospheric CO2 pathways into depositional sinks such as peats, swamps, and lakes. We explored the relationship between wetland sediment organic matter storage, climate (precipitation, temperature) and catchment vegetation data (catchment vegetation cover in percent" leaf carbon content in g/m2) by means of multivariate statistical analyses to investigate patterns of carbon deposition in modern wetlands and to provide a more robust framework for interpreting sediment bulk organic geochemistry as a proxy for past carbon cycling. Carbon and nitrogen elemental concentration and stable isotope composition were analyzed from sub-surface sediments at 18 wetlands in eastern Australia. The statistical analyses indicate that variability in geochemical organic matter data in wetland sediments is best explained by geographic differences in catchment vegetation cover and, by inference, the balance of terrestrial versus aquatic organic matter input to the sediment. TOC/TN of aquatic matter may be additionally driven toward higher (terrestrial) values by nitrogen limitation in the catchment and the lakes. These processes explain up to ∼40% of the total variance in the sediment geochemistry (redundancy analyses). Up to ∼10% of the total variance may be attributed to post-depositional processes and organic matter remineralization. The remaining ∼50% of total variance in the data may be attributed to local conditions across the sites, geochemical processes that were not captured in this study, or to the different timescales covered by the sediments at each site.</p>
Citation	Journal of Geophysical Research: Biogeosciences, 128(1), p. 1-17
ISSN	2169-8961 2169-8953
Link	https://hdl.handle.net/1959.11/57470
Publisher	Wiley-Blackwell Publishing, Inc
Rights	Attribution-NonCommercial 4.0 International
Title	Contemporary Controls on Terrestrial Carbon Characteristics in Temperate and Sub-Tropical Australian Wetlands
Type of document	Journal Article
Entity Type	Publication

Contemporary Controls on Terrestrial Carbon Characteristics in Temperate and Sub-Tropical Australian Wetlands

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