机构地区:[1]School of Geographical Sciences, Fujian Normal University [2]Key Laboratory of Humid Sub-tropical Eco-geographical Process of Ministry of Education of China, Fujian Normal University [3]Department of Geography and Resource Management, and Centre for Environmental Policy and Resource Management,The Chinese University of Hong Kong
出 处:《Journal of Environmental Sciences》2018年第3期72-82,共11页环境科学学报(英文版)
基 金:supported by the National Science Foundation of China (Nos. 41671088 and 41371127);the Program for Innovative Research Team of Fujian Normal University (No. IRTL1205);the Natural Science Foundation of Fujian Province, China (No. 2014J05046);the Study-Abroad Grant Project for Graduates of the School of Geographical Sciences, (No. GY201601);the Graduated Student Science and Technology Innovation Project of the School of Geographical Science,Fujian Normal University (No. GY201601)
摘 要:Aquaculture ponds are dominant features of the landscape in the coastal zone of China.Generally,aquaculture ponds are drained during the non-culture period in winter.However,the effects of such drainage on the production and flux of greenhouse gases(GHGs)from aquaculture ponds are largely unknown.In the present study,field-based research was performed to compare the GHG fluxes between one drained pond(DP,with a water depth of 0.05 m)and one undrained pond(UDP,with a water depth of 1.16 m)during one winter in the Min River estuary of southeast China.Over the entire study period,the mean CO2flux in the DP was(0.75±0.12)mmol/(m^2·hr),which was significantly higher than that in the UDP of(-0.49±0.09)mmol/(m^2·hr)(p0.01).This indicates that drainage drastically transforms aquaculture ponds from a net sink to a net source of CO2in winter.Mean CH4and N2O emissions were significantly higher in the DP compared to those in the UDP(CH4=(0.66±0.31)vs.(0.07±0.06)mmol/(m^2·hr)and N2O=(19.54±2.08)vs.(0.01±0.04)μmol/(m^2·hr))(p〈0.01),suggesting that drainage would also significantly enhance CH4and N2O emissions.Changes in environmental variables(including sediment temperature,p H,salinity,redox status,and water depth)contributed significantly to the enhanced GHG emissions following pond drainage.Furthermore,analysis of the sustained-flux global warming and cooling potentials indicated that the combined global warming potentials of the GHG fluxes were significantly higher in the DP than in the UDP(p〈0.01),with values of739.18 and 26.46 mg CO2-eq/(m^2·hr),respectively.Our findings suggested that drainage of aquaculture ponds can increase the emissions of potent GHGs from the coastal zone of China to the atmosphere during winter,further aggravating the problem of global warming.Aquaculture ponds are dominant features of the landscape in the coastal zone of China.Generally,aquaculture ponds are drained during the non-culture period in winter.However,the effects of such drainage on the production and flux of greenhouse gases(GHGs)from aquaculture ponds are largely unknown.In the present study,field-based research was performed to compare the GHG fluxes between one drained pond(DP,with a water depth of 0.05 m)and one undrained pond(UDP,with a water depth of 1.16 m)during one winter in the Min River estuary of southeast China.Over the entire study period,the mean CO2flux in the DP was(0.75±0.12)mmol/(m^2·hr),which was significantly higher than that in the UDP of(-0.49±0.09)mmol/(m^2·hr)(p0.01).This indicates that drainage drastically transforms aquaculture ponds from a net sink to a net source of CO2in winter.Mean CH4and N2O emissions were significantly higher in the DP compared to those in the UDP(CH4=(0.66±0.31)vs.(0.07±0.06)mmol/(m^2·hr)and N2O=(19.54±2.08)vs.(0.01±0.04)μmol/(m^2·hr))(p〈0.01),suggesting that drainage would also significantly enhance CH4and N2O emissions.Changes in environmental variables(including sediment temperature,p H,salinity,redox status,and water depth)contributed significantly to the enhanced GHG emissions following pond drainage.Furthermore,analysis of the sustained-flux global warming and cooling potentials indicated that the combined global warming potentials of the GHG fluxes were significantly higher in the DP than in the UDP(p〈0.01),with values of739.18 and 26.46 mg CO2-eq/(m^2·hr),respectively.Our findings suggested that drainage of aquaculture ponds can increase the emissions of potent GHGs from the coastal zone of China to the atmosphere during winter,further aggravating the problem of global warming.
关 键 词:Aquaculture pond Drainage management Greenhouse gas flux Global warming Min River estuary
分 类 号:X714[环境科学与工程—环境工程]
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