Litcius/Paper detail

Hydrology, vegetation, and soil properties as key drivers of soil organic carbon in coastal wetlands: A high-resolution study

Guo Mao, Lin Yang, Lei Zhang, Feixue Shen, Michael E. Meadows, Chenghu Zhou

2024Environmental Science and Ecotechnology45 citationsDOIOpen Access PDF

Abstract

Coastal wetlands are important blue carbon ecosystems that play a significant role in the global carbon cycle. However, there is insufficient understanding of the variations in soil organic carbon (SOC) stocks and the mechanisms driving these ecosystems. Here we analyze a comprehensive multi-source dataset of SOC in topsoil (0–20 cm) and subsoil (20–100 cm) across 31 coastal wetlands in China to identify the factors influencing their distribution. Structural equation models (SEMs) reveal that hydrology has the greatest overall effect on SOC in both soil layers, followed by vegetation, soil properties, and climate. Notably, the mechanisms driving SOC density differ between the two layers. In topsoil, vegetation type and productivity directly impact carbon density as primary sources of carbon input, while hydrology, primarily through seawater salinity, exerts the largest indirect influence. Conversely, in subsoil, hydrology has the strongest direct effect on SOC, with seawater salinity also influencing SOC indirectly through soil and vegetation mediation. Soil properties, particularly pH, negatively affect carbon accumulation, while climate influences SOC indirectly via its effects on vegetation and soil, with a diminishing impact at greater depths. Using Random Forest, we generate high-resolution maps (90 m × 90 m) of topsoil and subsoil carbon density ( R 2 of 0.53 and 0.62, respectively), providing the most detailed spatial distribution of SOC in Chinese coastal wetlands to date. Based on these maps, we estimate that SOC storage to a depth of 1 m in Chinese coastal wetlands totals 74.58 ± 3.85 Tg C, with subsoil carbon storage being 2.5 times greater than that in topsoil. These findings provide important insights into mechanism on driving spatial pattern of blue carbon and effective ways to assess carbon status on a national scale, thus contributing to the advancement of global blue carbon monitoring and management. • Soil carbon-environment relationship networks are constructed for topsoil and subsoil. • Hydrology is the dominant factor influencing SOC, followed by vegetation. • Vegetation directly influences surface SOC, while hydrology primarily controls subsoil SOC. • A 90 m × 90 m resolution SOC density map is generated for both topsoil and subsoil. • The coastal SOC storage in China is estimated 75 ± 4 Tg C to a depth of 1 m.

Topics & Concepts

TopsoilSoil carbonSubsoilEnvironmental scienceWetlandHydrology (agriculture)Vegetation (pathology)Soil scienceSoil waterGeologyEcologyPathologyBiologyGeotechnical engineeringMedicineCoastal wetland ecosystem dynamicsPeatlands and Wetlands EcologyGeology and Paleoclimatology Research