C. Cadier, N. Waltham, A. Canning, S. Fry, M. Adame
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引用次数: 0
摘要
在昆士兰,沿海湿地的潮汐限制改变了它们的水文联系,造成了淡水淤积的湿地,增加了甲烷的排放。我们调查了潮汐限制湿地的温室气体排放,并将其与邻近的潮汐连接湿地(盐沼和红树林)进行了比较。此外,还研究了季节和土壤理化参数对温室气体排放的影响。潮汐限制导致的甲烷排放量明显高于天然滨海湿地。土壤氧化还原、碳密度、氮密度和湿度均与甲烷排放呈显著相关。季节影响温室气体排放,夏季排放量较高。总体而言,受潮汐限制的湿地排放2175 mg co2 -eq . m2 .d -1,比潮汐连接的湿地排放18 mg co2 -eq . m2 .d -1高出两个数量级。这项研究支持昆士兰州的潮汐恢复作为一种具有成本效益的策略来缓解气候变化,因为它有可能提高蓝碳埋藏率并避免甲烷的长期排放。
Tidal Restriction Leads to Enhanced Methane Emissions in Tropical Australia
In Queensland, tidal restriction of coastal wetlands alters their hydrological connection and creates freshwater-impounded wetlands, increasing methane emissions. We investigated greenhouse gas emissions from tidally restricted wetlands and compared them with adjacent tidally connected wetlands (saltmarsh and mangroves). Furthermore, we investigated the influence of seasons and soil physicochemical parameters on greenhouse gas emissions. Tidal restriction leads to significantly higher methane emissions compared to natural coastal wetlands. Soil redox, carbon density, nitrogen density and moisture were all significantly correlated to methane emissions. Seasons influenced greenhouse gas emissions, with higher emissions in summer. Overall, tidally restricted wetlands were emitting 2175 mg CO 2-eq .m 2 .d -1 , two orders of magnitude higher than tidally connected wetlands which emitted 18 mg CO 2-eq .m 2 .d -1 . This research is supporting tidal restoration in Queensland as a cost-effective strategy to mitigate climate change as it has the potential to enhance blue carbon burial rates and avoids long-term emissions of methane.
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