Abstract
The conservation of coastal wetland ecosystems, like mangrove forests and salt marshes, represents a critical strategy for mitigating atmospheric emissions and climate change in the 21st century. Yet the existence of these environments is threatened by human-induced disturbances, namely deforestation and accelerated sea-level rise. Coastal systems maintain surface elevation in response to sea-level rise through a combination of physical and biological processes both above and below the ground surface. The quantification and relative contribution of belowground process controls (e.g., seasonal water content, organic matter decomposition) on surface elevation change is largely unexplored but crucial for informing coastal ecosystem sustainability. To address this knowledge deficit, we integrated measurements of surface elevation change of the live root zone (0.5 to 1 m depth) with geotechnical data from co-located sediment cores in the Sundarbans mangrove forest (SMF) of southwest Bangladesh. Core data reveal that the primary belowground controls on surface elevation change include seasonal fluctuations in pore-water content and the relative abundance of fine-grained sediments capable of volumetric expansion and contraction. In contrast to many mangrove environments, the soils of the SMF contain little organic matter and are dominantly composed (>90%) of inorganic clastic sediments. The mineral-rich soil texture likely leads to less compaction-induced subsidence as compared to organic-rich substrates and facilitates surface equilibrium in response to sea level rise. Despite a relatively high soil bulk density, soil carbon (C) density of the SMF is very low owing to the dearth of preserved organic content. However, rates of C accumulation are balanced out by locally high accretion rates, rendering the SMF a greater sink of terrestrial C than the worldwide mangrove average. The findings of this study demonstrate that C accumulation in the SMF, and possibly other alluvial mangrove forests, is highly dependent on the continued delivery of sediment to the mangrove platform and associated settings.
Highlights
Mangroves forests, and the ecosystems that they foster, are among the most valuable ecological and economic resources on Earth
We investigate the relative contributions of sedimentary and biotic parameters on controlling surface equilibrium of the live root zone” (LRZ), using the Sundarbans mangrove forest (SMF) of southwest Bangladesh as a study area
Studies reporting the relative importance of subsurface processes on changes in surface equilibrium are vital for understanding how mangrove forests and other coastal ecosystems will adjust to environmental disturbances, like locally accelerated sea-level rise [53]
Summary
Mangroves forests, and the ecosystems that they foster, are among the most valuable ecological and economic resources on Earth. Mangroves and other coastal vegetation represent a significant sink for atmospheric CO2 [9], and they will play a critical role in offsetting accelerated greenhouse gas emissions and resultant sea level rise in the 21st century [10,11]. While deforestation contributes to the degradation of mangroves, existing research identifies sea level rise as a primary threat to their survival (e.g., [14,15]), providing numerous examples of mangrove soil surfaces failing to keep pace with the combined effects of sea level rise and subsidence (i.e., “relative sea-level rise” [16,17,18,19]). Research efforts that quantify mangrove surface elevation dynamics in response to relative sea-level rise will be paramount for assessing the sustainability of these valuable ecosystems and into the future
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