Nature Communications (Dec 2023)

Carbonate chemistry and carbon sequestration driven by inorganic carbon outwelling from mangroves and saltmarshes

  • Gloria M. S. Reithmaier,
  • Alex Cabral,
  • Anirban Akhand,
  • Matthew J. Bogard,
  • Alberto V. Borges,
  • Steven Bouillon,
  • David J. Burdige,
  • Mitchel Call,
  • Nengwang Chen,
  • Xiaogang Chen,
  • Luiz C. Cotovicz,
  • Meagan J. Eagle,
  • Erik Kristensen,
  • Kevin D. Kroeger,
  • Zeyang Lu,
  • Damien T. Maher,
  • J. Lucas Pérez-Lloréns,
  • Raghab Ray,
  • Pierre Taillardat,
  • Joseph J. Tamborski,
  • Rob C. Upstill-Goddard,
  • Faming Wang,
  • Zhaohui Aleck Wang,
  • Kai Xiao,
  • Yvonne Y. Y. Yau,
  • Isaac R. Santos

DOI
https://doi.org/10.1038/s41467-023-44037-w
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 8

Abstract

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Abstract Mangroves and saltmarshes are biogeochemical hotspots storing carbon in sediments and in the ocean following lateral carbon export (outwelling). Coastal seawater pH is modified by both uptake of anthropogenic carbon dioxide and natural biogeochemical processes, e.g., wetland inputs. Here, we investigate how mangroves and saltmarshes influence coastal carbonate chemistry and quantify the contribution of alkalinity and dissolved inorganic carbon (DIC) outwelling to blue carbon budgets. Observations from 45 mangroves and 16 saltmarshes worldwide revealed that >70% of intertidal wetlands export more DIC than alkalinity, potentially decreasing the pH of coastal waters. Porewater-derived DIC outwelling (81 ± 47 mmol m−2 d−1 in mangroves and 57 ± 104 mmol m−2 d−1 in saltmarshes) was the major term in blue carbon budgets. However, substantial amounts of fixed carbon remain unaccounted for. Concurrently, alkalinity outwelling was similar or higher than sediment carbon burial and is therefore a significant but often overlooked carbon sequestration mechanism.