三峡库区汉丰湖水体CO<sub>2</sub>及CH<sub>4</sub>排放特征及影响因素

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摘要利用漂浮箱法与顶空平衡法对汉丰湖水体CO₂与CH₄排放通量及溶存浓度进行逐月观测,探讨了其时空特征及影响因素.结果表明:汉丰湖水体CO₂排放通量为-64.3~128.4mmol/(m²·d),平均值为(35.8±45.2)mmol/(m²·d),远低于三峡库区其他水域的排放水平,是CO₂的排放弱源;CH₄通量平均值为(3.87±5.08)mmol/(m²·d),尽管变异性强(0.43~36.93mmol/(m²·d)),但平均水平远高于三峡其他水域,是大气CH₄排放的强源;汉丰湖水域每年向大气排放CO₂和CH₄总量分别为1415.48和133.54t,占汉丰湖水体碳总储量的26.86%,是一个活跃的碳代谢水域.汉丰湖CO₂排放通量自1~12月呈先显著降低后迅速升高的季节模式,CH₄呈几乎相反的季节变化,但二者季节动态均受水位调度的强烈干扰.三峡高水位期汉丰湖表现为高CO₂低CH₄排放的特征,汉丰湖水位期则呈低CO₂高CH₄排放,三峡回水扰动期CO₂和CH₄排放均较强.相关分析表明,CO₂排放通量主要与Chl-a、藻密度、以及pH值等呈显著负相关关系,水体藻类繁殖导致初级生产的变化是主导CO₂排放季节动态的关键,导致水体出现明显的CO₂源-汇转变, CH₄排放通量与水体TOC、DOC、TN、NO₃^--N、藻密度等呈显著正相关关系,表明水体养分积累以及藻类代谢共同主导了CH₄排放的季节动态.汉丰湖CO₂排放通量呈自上游向下游先降低后升高的空间分异,而CH₄相反,这种空间分异受到汉丰湖入库河流的汇入及水位调度的共同影响.总之,水位调度明显干扰了水环境参数与碳排放的关联关系,导致不同水位期CO₂和CH₄排放通量的关键指示因子不同.

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关键词 ：汉丰湖, 双重水位调节, CO₂与CH₄排放, 时空动态, 影响因素

Abstract：This study investigated the fluxes and concentrations of CO₂ and CH₄ in Hanfeng Lake, using the floating chamber method and headspace equilibrium method, to reveal spatio-temporal dynamics and driving factors of CO₂ and CH₄ emissions under varing water level fluctuations. The results showed that Hanfeng Lake was a weak CO₂ emission source, with a flux range of -64.34 to 128.37mmol/(m²·d) and an average of (35.8±45.2)mmol/(m²·d), which was much lower than that of other waters in the Three Gorges Reservoir. Meanwhile, Hanfeng Lake was a strong CH₄ emission source. Although the CH₄ flux showed strong variations with ranges of 0.43~36.93mmol/(m²·d), its average value ((3.87±5.08)mmol/(m²·d)) was much higher than that of other regions in the Three Gorges Reservoir. The total emissions of CO₂ and CH₄ emitted to the atmosphere by Hanfeng Lake was 1415.48 and 133.54t, respectively, accounting for 26.86% of the total carbon storage of Hanfeng Lake, which indicated that Hanfeng Lake had an active carbon metabolism. From January to December, the CO₂ emission flux in Hanfeng Lake showed a seasonal pattern of significant decrease and then rapid increase, and CH₄ showed an almost opposite seasonal change. The seasonal dynamics were strongly disturbed by the double-water-level regulation. Higher CO₂ and lower CH₄ emission during the high water level period of the Three Gorges. During the Hanfeng water level period, CO₂ emission was weaker, but CH₄ emission was stronger. CO₂ and CH₄ emissions were stronger during the Three Gorges backwater period. Correlation analysis showed that CO₂ emission flux was negatively correlated with Chl-a, algal density and pH. The change of primary production caused by algae blooms was the key factor to dominate the seasonal dynamics of CO₂ emissions, and even led to the obvious CO₂ source-sink transition in Hanfeng Lake. CH₄ fluxes were positively correlated with TOC, DOC, TN, NO₃^--N and algal density, indicating that the seasonal dynamics of CH₄ emission were dominated by nitrogen accumulation and algal metabolism. The CO₂ emission flux in Hanfeng Lake showed a spatial characteristic of first decreasing and then increasing from upstream to downstream, which was opposite to the spatial dynamic of CH₄ emission flux. This spatial characteristic was caused by the incoming rivers and water level fluctuation. In general, water level fluctuation obviously interfered with the correlation between water environment parameters and carbon emissions, resulting in different key indicators of CO₂ and CH₄ emission fluxes at different water levels.

Key words： Hanfeng Lake double-water-level regulation CO₂ and CH₄ fluxes spatial-temporal variations influencing factors

收稿日期: 2024-05-15

PACS:	X511
	X524

基金资助:国家自然科学基金资助项目(32371680);重庆市自然科学基金资助项目(2022NSCQ-MSX2598);重庆市教委研究项目(KJQN202200536,KJZD-K202000502);大学生创新创业训练计划项目(202210637007)

通讯作者: 王晓锋,教授,xiaofeng6540@163.com E-mail: xiaofeng6540@163.com

作者简介: 蹇陈(2000-),男,四川营山人,重庆师范大学硕士研究生,研究方向为淡水生态系统碳循环.jianchen1129@163.com.

引用本文:

蹇陈, 杨艺, 刘婷婷, 龚小杰, 王晓锋. 三峡库区汉丰湖水体CO₂及CH₄排放特征及影响因素[J]. 中国环境科学, 2024, 44(12): 7046-7062. JIAN Chen, YANG Yi, LIU Ting-ting, GONG Xiao-jie, WANG Xiao-feng. Spatial-temporal dynamics and influencing factors of CO₂ and CH₄ fluxes in a double-water-level regulated Hanfeng Lake in the Three Gorges Reservoir. CHINA ENVIRONMENTAL SCIENCECE, 2024, 44(12): 7046-7062.

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