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引用本文:金业,陈小强,廖苗苗,关昊鹏,赵化德,许士国.大型水库分层期和混合期溶存温室气体空间变化及排放通量.湖泊科学,2023,35(3):1082-1096. DOI:10.18307/2023.0326
Jin Ye,Chen Xiaoqiang,Liao Miaomiao,Guan Haopeng,Zhao Huade,Xu Shiguo.Spatial variations of dissolved greenhouse gases and emission fluxes in a large reservoir during the stratification and mixing periods. J. Lake Sci.2023,35(3):1082-1096. DOI:10.18307/2023.0326
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大型水库分层期和混合期溶存温室气体空间变化及排放通量
金业1, 陈小强1, 廖苗苗1, 关昊鹏1, 赵化德2, 许士国1
1.大连理工大学建设工程学部水环境研究所, 大连 116024;2.国家海洋环境监测中心, 大连 116023
摘要:
水库作为温室气体的重要来源,对区域气候变化有不可忽略的影响。然而,目前对水库溶存温室气体的空间异质性及垂向特征的认知仍然欠缺。为了揭示水库分层期和混合期溶存温室气体空间特征及排放通量,也为厘清水库温室气体产生和排放的关键过程提供重要支撑。研究选择东北地区大型水库——汤河水库为对象,于2021年7—9月和10月(分别代表水库分层期和混合期)对水库不同位置(坝前、库中和库尾)开展溶存温室气体垂向分层监测。研究结果显示,水库CH4排放通量变化范围为0.018~0.174 mmol/(m2·d),是大气CH4的源,空间分布为库尾>库中>坝前;CO2通量为-4.91~58.77 mmol/(m2·d),除分层期东支库尾,其余点位均表现为大气CO2的源,空间分布为坝前>库中>库尾。时间上,分层期CH4排放通量(0.071±0.044 mmol/(m2·d))高于混合期((0.027±0.008) mmol/(m2·d));分层期CO2排放通量((5.12±5.50) mmol/(m2·d))明显低于混合期((42.76±16.72) mmol/(m2·d))。水温和径流的变化共同影响CH4和CO2排放通量。结合水库溶存温室气体垂向分布特征,水库CH4的生成热区主要在坝前和库尾。分层期的水库溶存CH4在坝前和库中底层大量累积,原因是等温层的持续缺氧以及上下水层的交换能力限制。与国内其它水库温室气体排放通量对比发现,水库的不同时期(分层期和混合期)、空间位置(坝前、库中和库尾)以及库龄是准确评估水库温室气体排放的关键因素。
关键词:  汤河水库  溶存温室气体  分层期  混合期  排放通量
DOI:10.18307/2023.0326
分类号:
基金项目:国家自然科学基金项目(42077348)和国家重点研发计划项目(2019YFC1407700)联合资助。
Spatial variations of dissolved greenhouse gases and emission fluxes in a large reservoir during the stratification and mixing periods
Jin Ye1, Chen Xiaoqiang1, Liao Miaomiao1, Guan Haopeng1, Zhao Huade2, Xu Shiguo1
1.Institute of Water and Environmental Research, Faculty of Infrastructure Engineering, Dalian University of Technology, Dalian 116024, P. R. China;2.National Marine Environmental Monitoring Center, Dalian 116023, P. R. China
Abstract:
Reservoirs are pivotal sources of greenhouse gases (GHGs) to the atmosphere that may influence regional climate change. However, the spatial heterogeneity and the vertical characteristics of dissolved GHGs in reservoirs are still poorly understood. This study aimed to reveal the characteristics of greenhouse gases dissolution and emission fluxes in reservoirs during stratification and mixing periods, and to provide important supports to clarify the key processes of GHGs production and emission in reservoirs. We selected Tanghe Reservoir, a large reservoir in Northeast China, and conducted vertical stratified monitoring of dissolved GHGs at different locations (in front of dam, mid, end transects) from July-September and October 2021 (representing the stratification and mixing periods, respectively). The results showed that the CH4 fluxes ranged from 0.018-0.174 mmol/(m2·d) and all sites were the source of CH4, the spatial distribution of CH4 fluxes was end>mid>in front of dam. The CO2 fluxes ranged from -4.91-58.77 mmol/(m2·d), and all sites were the source of CO2 except for the eastern end transect during the stratified period, and the contents of spatial distribution of CO2 fluxes was in front of dam>mid>end. In terms of temporal differences, CH4 fluxes in the stratified period ((0.071±0.044) mmol/(m2·d)) were higher than in the mixed period ((0.027±0.008) mmol/(m2·d)), and CO2 fluxes in the stratified period ((5.12±5.50) mmol/(m2·d)) were lower than the mixed period ((42.76±16.72) mmol/(m2·d)), and both water temperature and runoff affected CH4 and CO2 fluxes. The vertical distribution characteristics of dissolved GHGs indicated that the hot zone of reservoir CH4 generation was mainly in front of dam and end transects. The CH4 was heavily accumulated in the bottom water of the dam front and mid transects during the stratified period due to the persistent anoxia in the hypolimnion and the limitation of the exchange capacity in the water column. The comparison with other reservoirs GHGs fluxes in China revealed that the different periods (stratification and mixing period), spatial variations (in front of dam, mid, and end transects) and reservoir ages were the key factors for accurate assessment of reservoir GHGs emissions.
Key words:  Tanghe Reservoir  dissolved greenhouse gases  stratification period  mixing period  emission flux
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