| 覆盖层甲烷氧化动力学和甲烷氧化菌群落结构 |
| 摘要点击 1508 全文点击 935 投稿时间:2015-04-28 修订日期:2015-06-25 |
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| 中文关键词 填埋场覆盖层 连续监测 动力学 甲烷氧化菌 群落结构 |
| 英文关键词 landfill cover continuous monitoring kinetics methanotrophs community structure |
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| 中文摘要 |
| 基于实际填埋场覆盖土建立了可实时在线监测生物气的模拟覆盖层系统,连续监测了不同垂直梯度生物气浓度变化. 甲烷通量不变时,覆盖层内不同梯度生物气浓度基本保持不变,系统持续稳定运行,甲烷通量变化后2~3 h生物气可再次持续稳定. 考察了覆盖层甲烷氧化特性与甲烷通量的关系,深度大于20 cm,氧气浓度随甲烷通量的增大呈减小趋势,表层氧气浓度与甲烷通量无相关性,不同梯度的甲烷氧化速率与甲烷通量呈正相关(R2变化范围0.851~0.999). 为避免覆盖土脱离系统环境造成的误差,以动态连续监测结果为基础,利用双基质Michaelis-Menten方程拟合了覆盖层甲烷氧化动力学(R2范围为0.902~0.955),得到覆盖土半饱和常数Km为0.157~0.729,Km随深度的增加而增大. 利用高通量测序技术分析了原始覆盖土和经模拟覆盖层运行后的甲烷氧化菌群落结构,运行后甲烷氧化菌OUT数量显著增多,优势菌群为Ⅰ型菌的Methylobacter和Methylophilaceae及Ⅱ型菌Methylocystis. |
| 英文摘要 |
| Simulated landfill cover with real time online monitoring system was developed using cover soils. Then the system started and the concentrations of bio-gas in various depths were continuously monitored, and it was found that the system ran continually and stably after 2-3 h when methane flux changed. After that, the relationship between regularity of methane oxidation and methane flux in landfill cover was analyzed. The results indicated that concentration of oxygen decreased with increasing methane flux when the depth was deeper than 20 cm, and no obvious correlation between oxygen concentration in landfill cover surface and methane flux, however, methane oxidation rate showed positive correlation with methane flux in various depths (range of R2 was 0.851-0.999). Kinetics of CH4 oxidation in landfill cover was fitted by CH4-O2 dual-substrate model (range of R2 was 0.902-0.955), the half-saturation constant Kmincreasing with depth was 0.157-0.729 in dynamic condition. Finally, methanotrophs community structure in original cover soil sample and that in simulated landfill cover were investigated by high-throughout sequencing technology, and the statistics indicated that the abundance and species of methanotrophs in simulated landfill cover significantly increased compared with those in original cover soil sample, and type Ⅰ methanotrophs including Methylobacter and Methylophilaceae and type Ⅱ methanotrophs Methylocystis were dominant species. |
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