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Global patterns of organic carbon transfer and accumulation across the land–ocean continuum constrained by radiocarbon data
Wang, C.; Qiu, Y.; Hao, Z.; Wang, J.; Zhang, C.; Middelburg, J.J.; Wang, Y.; Zou, X. (2024). Global patterns of organic carbon transfer and accumulation across the land–ocean continuum constrained by radiocarbon data. Nature Geoscience 17(8): 778-786. https://dx.doi.org/10.1038/s41561-024-01476-4
In: Nature Geoscience. Nature Publishing Group: London. ISSN 1752-0894; e-ISSN 1752-0908, more
Peer reviewed article  

Available in  Authors 

Keyword
    Marine/Coastal

Authors  Top 
  • Wang, C.
  • Qiu, Y.
  • Hao, Z.
  • Wang, J.
  • Zhang, C.
  • Middelburg, J.J., more
  • Wang, Y.
  • Zou, X.

Abstract
    Radiocarbon (Δ14C) serves as an effective tracer for identifying the origin and cycling of carbon in aquatic ecosystems. Global patterns of organic carbon (OC) Δ14C values in riverine particles and coastal sediments are essential for understanding the contemporary carbon cycle, but are poorly constrained due to under-sampling. This hinders our understanding of OC transfer and accumulation across the land–ocean continuum worldwide. Here, using machine learning approaches and >3,800 observations, we construct a high-spatial resolution global atlas of Δ14C values in river–ocean continuums and show that Δ14C values of river particles and corresponding coastal sediments can be similar or different. Specifically, four characteristic OC transfer and accumulation modes are recognized: the old–young mode for systems with low river and high coastal sediment Δ14C values; the young–old and old–old modes for coastal systems with old OC accumulation receiving riverine particles with high and low Δ14C values, respectively; and the young–young mode with young OC for both riverine and coastal deposited particles. Distinguishing these modes and their spatial patterns is critical to furthering our understanding of the global carbon system. Specifically, among coastal areas with high OC contents worldwide, old–old systems are largely neutral to slightly negative to contemporary atmospheric carbon dioxide (CO2) removal, whereas young–old and old–young systems represent CO2 sources and sinks, respectively. These spatial patterns of OC content and isotope composition constrain the local potential for blue carbon solutions.

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