Impact of Source Variability and Hydrodynamic Forces on the Distribution, Transport, and Burial of Sedimentary Organic Matter in a Tropical Coastal Margin: The Gulf of Thailand

Carbon cycling in the tropical margin is more extensive compared with other regions of the world. The goal of this study was to better understand the origins, transport, and burial of sedimentary organic matter (SOM) in the Gulf of Thailand (GOT) from the coastal margin of Southeast (SE) Asia, which...

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Bibliographic Details
Published in:Journal of geophysical research. Biogeosciences 2021-09, Vol.126 (9), p.n/a
Main Authors: Bai, Yazhi, Hu, Limin, Wu, Bin, Qiao, Shuqing, Fan, Dejiang, Liu, Shengfa, Yang, Gang, Liu, Jihua, Kornkanitnan, Narumol, Khokiattiwong, Somkiat, Shi, Xuefa
Format: Article
Language:English
Subjects:
Accumulation
Alkanes
Anthropogenic factors
Carbon
Carbon cycle
Carbon isotope ratio
Carbon isotopes
Chemical composition
Coastal plains
Coastal zone
Dispersal
Dispersion
Distribution
Estuaries
Estuarine dynamics
Forces
Gulf of Thailand
Heterogeneity
Human influences
hydrodynamic sorting
Hydrodynamics
Isotope ratios
lipid biomarkers
Molecular weight
Offshore
Organic carbon
Organic matter
Patchiness
Petroleum
Principal components analysis
sediment organic matter
Sediments
source variability
Spatial heterogeneity
Transport
Tropical climate
Variability
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Summary:Carbon cycling in the tropical margin is more extensive compared with other regions of the world. The goal of this study was to better understand the origins, transport, and burial of sedimentary organic matter (SOM) in the Gulf of Thailand (GOT) from the coastal margin of Southeast (SE) Asia, which serve as a major depository of fine‐grained sediments and the associated organic carbon (OC). The results revealed a variety of organic matter (OM) inputs and the selective transport of fine sediment, resulting in preferential dispersal of terrigenous SOM in the GOT. Bulk OC indices with low carbon/nitrogen ratios and enriched stable carbon isotope ratios (−24.2‰ to −20.4‰, and mean −21.4 ± 0.56‰) are likely related to the presence of marine‐derived OM and anthropogenic interference. A binary mixing model further clarified the significant contributions of terrestrial derived‐OM within the upper and central GOT. The n‐alkane compositions and principal component analysis indicated that a majority of the terrigenous SOM settles within the estuary in the upper GOT, while a selective dispersal of land‐based SOM through long‐distance transport toward the modern depocenter in the lower GOT. The characteristics of lower molecular weight n‐alkanes also suggest anthropogenic OM input from petroleum‐related contributions. Altogether, the depositional patterns and spatial heterogeneity of the SOM indicated by both the bulk and molecular signatures reveal the important roles of source variability and the selective dispersal of land‐based OM on the supply and accumulation of OC in the tropical coastal margin. Plain Language Summary The accumulation and fate of sedimentary organic carbon (OC) in the tropical coastal system are significant components of the global carbon cycling. In order to elucidate the distribution and accumulation of organic matter (OM) in tropical regimes, this study first explored the concentration and composition of sedimentary OC based on the bulk and molecular‐level data, and then depicted the modern transport pattern of OM in the Gulf of Thailand (GOT). This study showed terrestrial input accounted for 5%–64% (20% ± 8% on average) of the OM and dominated in the upper GOT, the offshore depocenter in the northeastern GOT and north of Samui Island. Molecular composition of n‐alkanes and principal component analysis result showed that the hydrodynamic condition plays a significant role on the selective dispersal of terrigenous OM from the coastal region t
ISSN:2169-8953
2169-8961
DOI:10.1029/2021JG006434