Global management of wetlands to suppress greenhouse gas (GHG) emissions, facilitate carbon (C) sequestration, and reduce atmospheric CO2 concentrations while simultaneously promoting agricultural gains is paramount. However, studies that relate variability in CO2 and CH4 emissions at large spatial scales are limited. We investigated three-year emissions of soil CO2 and CH4 from the primary wetland types of the Liaohe Delta, China, by focusing on a total wetland area of 3287 km2. One percent is Suaeda salsa, 24% is Phragmites australis, and 75% is rice. While S. salsa wetlands are under somewhat natural tidal influence, P. australis and rice are managed hydrologically for paper and food, respectively. Total C emissions from CO2 and CH4 from these wetland soils were 2.9 Tg C/year, ranging from 2.5 to 3.3 Tg C/year depending on the year assessed. Primary emissions were from CO2 (~98%). Photosynthetic uptake of CO2 would mitigate most of the soil CO2 emissions, but CH4 emissions would persist. Overall, CH4 fluxes were high when soil temperatures were >18°C and pore water salinity <18 PSU. CH4 emissions from rice habitat alone in the Liaohe Delta represent 0.2% of CH4 carbon emissions globally from rice. With such a large area and interannual sensitivity in soil GHG fluxes, management practices in the Delta and similar wetlands around the world have the potential not only to influence local C budgeting, but also to influence global biogeochemical cycling.
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机译:对湿地进行全球管理,以抑制温室气体(GHG)排放,促进碳(C)隔离,降低大气中的CO2浓度,同时促进农业增收至关重要。但是,有关大空间尺度上CO2和CH4排放变化的研究有限。以辽河三角洲主要湿地类型为研究对象,研究了三年来土壤CO2和CH4的排放量,重点是总湿地面积3287 km 2 。 Suaeda salsa为1%,Phragmites australis为24%,大米为75%。沙门氏菌湿地在一定程度上受到自然潮汐的影响,而澳大利亚对虾和稻米的水文管理分别用于纸张和食物。来自这些湿地土壤的CO2和CH4的总碳排放量为2.9 Tg C /年,取决于评估年份,范围为2.5至3.3 Tg C /年。一次排放来自二氧化碳(约98%)。光合作用吸收二氧化碳将减轻大部分土壤二氧化碳的排放,但甲烷的排放将持续下去。总体而言,当土壤温度> 18°C和孔隙水盐度<18 PSU时,CH4通量较高。仅辽河三角洲稻米栖息地的CH4排放量占全球稻米CH4碳排放量的0.2%。如此大的面积和对土壤温室气体通量的年际敏感性,三角洲和世界各地类似湿地的管理实践不仅有可能影响当地的碳预算,而且有可能影响全球生物地球化学循环。
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