AI Article Synopsis
- Coastal wetlands are highly productive ecosystems that significantly contribute to methane emissions, but converting them into aquaculture ponds impacts methane production and microbial communities.
- A study in southeastern China found that aquaculture ponds had lower methane production potential, soil organic carbon (SOC), total nitrogen content, and a different carbon/nitrogen ratio compared to coastal marshes.
- The decline in methane production in aquaculture ponds is linked to changes in soil properties and the abundance of methanogenic archaea, highlighting the need for better carbon models to predict impacts from wetland conversion on climate change.
Article Abstract
Coastal wetlands are among the most productive and dynamic ecosystems globally, contributing significantly to atmospheric methane (CH) emissions. The widespread conversion of these wetlands into aquaculture ponds degrades these ecosystems, yet its effects on CH production and associated microbial mechanisms are not well understood. This study aimed to assess the impact of land conversion on CH production potential, total and active soil organic C (SOC) content, and microbial communities. We conducted a comparative study on three brackish marshes and adjacent aquaculture ponds in southeastern China. Compared to costal marshes, aquaculture ponds exhibited significantly (P < 0.05) lower CH production potential (0.05 vs. 0.02 μg kg h), SOC (17.64 vs. 6.97 g kg), total nitrogen (TN) content (1.62 vs. 1.24 g kg) and carbon/nitrogen (C/N) ratio (10.85 vs. 5.66). CH production potential in aquaculture ponds was influenced by both microbial and abiotic factors. Specifically, the relative abundance of Methanosarcina slightly decreased in aquaculture ponds, while the potential for CH production declined with lower SOC contents and C/N ratio. Overall, our findings demonstrate that converting natural coastal marshes into aquaculture ponds reduces CH production by altering key soil properties and the structure and diversity of methanogenic archaea communities. These results provide empirical evidence to enhance global carbon models, improving predictions of carbon feedback from wetland land conversion in the context of climate change.
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| http://dx.doi.org/10.1016/j.watres.2024.122608 | DOI Listing |
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