Abstract
Methane (CH4) emissions from estuarine wetlands were proved to be influenced by tide movement and inundation conditions notably in many previous studies. Although there have been several researches focusing on the seasonal or annual CH4 emissions, the short-term CH4 emissions during the tide cycles were rarely studied up to now in this area. In order to investigate the CH4 emission pattern during a tide cycle in Yangtze Estuary salt marshes, frequent fixed-point observations of methane flux were carried out using the in-situ static closed chamber technique. The results indicated that the daily average CH4 fluxes varied from 0.68 mgCH4·m−2·h−1 to 4.22 mgCH4·m−2·h−1 with the average flux reaching 1.78 mgCH4·m−2·h−1 from small tide to spring tide in summer. CH4 fluxes did not show consistent variation with both tide levels and inundation time but increased steadily during almost the whole research period. By Pearson correlation analysis, CH4 fluxes were not correlated with both tide levels (R = −0.014, p = 0.979) and solar radiation (R = 0.024, p = 0.865), but significantly correlated with ambient temperature. It is temperature rather than the tide level mainly controlling CH4 emissions during the tide cycles. Besides, CH4 fluxes also showed no significant correlation with the underground pore-water CH4 concentrations, indicating that plant-mediated transport played a more important role in CH4 fluxes compared with its production and consumption.
Highlights
Published: 11 February 2021Methane (CH4 ) ranks second to carbon dioxide (CO2 ) as an important greenhouse gas (GHG) without considering water vapor [1]
This study suggested that CH4 emissions varied significantly during the tide cycles
The sediment–air CH4 fluxes increased from 0.68 to 4.22 mgCH4 ·m−2 ·h−1 during the days’ tidal cycle from 10 July to 24 July. This demonstrated that July is a critical devel15 days’ tidal cycle from 10 July to 24 July. This demonstrated that July is a critical developopmental period for CH4 emissions in the Yangtze estuary intertidal zones
Summary
Published: 11 February 2021Methane (CH4 ) ranks second to carbon dioxide (CO2 ) as an important greenhouse gas (GHG) without considering water vapor [1]. Wetlands are the single biggest CH4 source type, driven by their sufficient sediment organic carbon (SOC) supply and a strict anaerobic environment [4,5,6]. Wetland CH4 emission is a very complex process under the comprehensive effects of the environmental factors, including inundation conditions [9], carbon availability [5], temperature [10], salinity [11] and vegetation [12]. The above environmental factors mainly influence CH4 production and emission via changing the redox status, the microbial activity, Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
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