Journal
EARTH AND PLANETARY SCIENCE LETTERS
Volume 505, Issue -, Pages 76-85Publisher
ELSEVIER SCIENCE BV
DOI: 10.1016/j.epsl.2018.10.013
Keywords
radiocarbon; C-14 heterogeneity; grain size fractions; organic carbon; continental shelf sediments; hydrodynamic processes
Categories
Funding
- SNF CAPS-LOCK project [200021_140850]
- National Natural Science Foundation of China [41520104009, U1706219]
- 111 project [B13030]
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The deposition and long-term burial of sedimentary organic matter (OM) on continental margins comprises a fundamental component of the global carbon cycle. A key unknown in interpretation of carbon isotope records of sedimentary OM is the extent to which OM accumulating in continental shelf and slope sediments is influenced by dispersal and redistribution processes. Here, we present results from an extensive survey of organic carbon (OC) characteristics of grain size fractions (ranging from <20 to 250 mu m) retrieved from Chinese marginal sea surface sediments in order to assess the extent to which the abundance and isotope composition of OM in shallow shelf seas is influenced by hydrodynamic processes. Our findings show that contrasting relationships exist between C-14 contents of OC and grain size in surface sediments associated with two different hydrodynamic modes, suggesting that transport pathways and mechanisms imparted by the different hydrodynamic conditions exert a strong influence on C-14 contents of OM in continental shelf sediments. In deeper regions and erosional areas, we infer that bedload transport exerts the strongest influence on (decreases) OC C-14 contents of the coarser fraction, while resuspension processes induce OC C-14 depletion of intermediate grain size fractions in shallow inner-shelf settings. We use the inter-fraction spread in Delta C-14 values, defined here as H-14, to argue that the hydrodynamic processes amplify overall C-14 heterogeneity within corresponding bulk sediment samples. The magnitude and footprint of this heterogeneity carries implications for our understanding of carbon cycling in shallow marginal seas. (C) 2018 The Author(s). Published by Elsevier B.V.
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