ENHANCED NITRIFICATION AND DENITRIFICATION BY COUPLING MICROBIAL ELECTROLYSIS CELL IN A SINGLE BED VERTICAL FLOW CONSTRUCTED WETLAND
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摘要: 为探究微生物电解池对人工湿地硝化反硝化脱氮的强化效果,构建了闭路运行(VFCW-MEC)与开路运行(VFCW-C)的垂直潜流人工湿地-微生物电解池系统,研究了不同外加电压(0,0.2,0.4 V)下耦合湿地系统的脱氮效能差异及N2O排放特征。结果表明:施加外加电压的VFCW-MEC对NH4-N和TN的去除效率均高于VFCW-C,外加电压为0,0.2,0.4 V时,VFCW-MEC对NH4+-N的去除率分别为(61.66±0.30)%、(69.21±0.31)%和(74.82±0.27)%,TN去除率分别为(11.53±0.35)%、(20.06±0.59)%和(33.29±0.35)%,这些现象表明,外加电压有助于提升湿地系统对NH4+-N和TN的去除效率。通过解析VFCW-MEC系统阳极和阴极区域氮浓度变化规律,发现阳极和阴极分别加强了垂直潜流湿地的硝化和反硝化作用,微生物产氢和直接电子传递作用共同促进了阴极反硝化脱氮效率。值得注意的是,外加电压也增加了脱氮过程中N2O的排放效率,不利于温室气体的减排。以上研究表明:微生物电解池在强化潜流人工湿地硝化反硝化脱氮方面具有良好潜力。Abstract: To investigate the effect of microbial electrolysis cells on the nitrification and denitrification performance of constructed wetlands, vertical flow constructed wetland-microbial electrolysis cell systems with closed circuit operation (VFCW-MEC) and open circuit operation (VFCW-C) were constructed. The nitrogen removal performance and N2O emission characteristics of the coupled wetland systems with different external voltages (0, 0.2, 0.4 V) were investigated. The results showed that NH4-N and TN removal efficiencies of VFCW-MEC were higher than that of VFCW-C, and the NH4-N removal efficiencies of VFCW-MEC at external voltages of 0, 0.2, 0.4 V were (61.66±0.30)%, (69.21±0.31)% and (74.82±0.27)%, respectively, and the corresponding values for TN were (11.53±0.35)%, (20.06±0.59)% and (33.29±0.35)%, respectively. These observations indicated that the external voltage can enhance the NH4+-N and TN removal efficiency of the wetland system. By analysing the variation patterns of nitrogen concentration in the anode and cathode zones of the VFCW-MEC system, it was found that the anode and cathode enhanced nitrification and denitrification efficiencies, respectively. Microbial hydrogen production and direct electron transfer contributed to the enhanced denitrification efficiency in the cathode. It is worth that the external voltage increases the efficiency of N2O emission, which is not conducive to greenhouse gas reduction. These findings show the potential of microbial electrolytic cells for enhancing nitrogen removal of constructed wetlands.
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