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改性蓝藻生物炭促进生物电化学系统阴极氢自养反硝化过程研究

熊江磊 罗嘉豪 严群

熊江磊,罗嘉豪,严群.改性蓝藻生物炭促进生物电化学系统阴极氢自养反硝化过程研究[J].环境工程技术学报,2022,12(5):1640-1646 doi: 10.12153/j.issn.1674-991X.20210362
引用本文: 熊江磊,罗嘉豪,严群.改性蓝藻生物炭促进生物电化学系统阴极氢自养反硝化过程研究[J].环境工程技术学报,2022,12(5):1640-1646 doi: 10.12153/j.issn.1674-991X.20210362
XIONG J L,LUO J H,YAN Q.Research on modified cyanobacterial biochar promoting cathodic hydrogen autotrophic denitrification in bioelectrochemical system[J].Journal of Environmental Engineering Technology,2022,12(5):1640-1646 doi: 10.12153/j.issn.1674-991X.20210362
Citation: XIONG J L,LUO J H,YAN Q.Research on modified cyanobacterial biochar promoting cathodic hydrogen autotrophic denitrification in bioelectrochemical system[J].Journal of Environmental Engineering Technology,2022,12(5):1640-1646 doi: 10.12153/j.issn.1674-991X.20210362

改性蓝藻生物炭促进生物电化学系统阴极氢自养反硝化过程研究

doi: 10.12153/j.issn.1674-991X.20210362
基金项目: 江苏省“双创博士”企业创新类人才项目(〔2019〕30279号);江苏省“双创人才”项目(〔2020〕10342号)
详细信息
    作者简介:

    熊江磊(1984—),男,高级工程师,博士,研究方向为工业废水的处理及资源化,xiongjianglei@hotmail.com

  • 中图分类号: X52,X703

Research on modified cyanobacterial biochar promoting cathodic hydrogen autotrophic denitrification in bioelectrochemical system

  • 摘要:

    以太湖蓝藻为原料制备不同种类的活性生物炭,并将其投入到生物电化学系统(BES)的阴极促进氢自养反硝化。通过扫描电镜、能谱仪和傅里叶红外光谱对未经改性(ABC-800)、硝酸改性(ABC-800N)和KOH改性(ABC-800K)3组蓝藻生物炭进行观察,并与不加入蓝藻生物炭的对照组进行比较,以考察生物炭促进BES生物阴极的反硝化过程中的电子传递机制。结果表明:ABC-800N表面的N、O元素含量最高,同时与电子传递能力及生物相容性相关的共轭醌、酮结构的丰度也最高;将蓝藻生物炭投加至BES的非生物阴极中可提高阴极的脱氮效率,ABC-800N投加量为0.5 g时,7 d内脱氮效率达到最高,为96.0%,而对照组仅为29.6%;高通量测序表明,ABC-800N组的优势菌属为Thauera、JGI_0001001_H03、ThiobacillusDenitratisoma等。

     

  • 图  1  3种生物炭材料的表面形貌

    Figure  1.  Surface morphology of the three biochar materials

    图  2  3种生物炭材料表面N元素含量分布

    Figure  2.  Distribution of N element content on the surface of three biochar materials

    图  3  3种生物炭材料表面O元素含量分布

    Figure  3.  Distribution of O element content on the surface of three biochar materials

    图  4  3种生物炭的N2吸附-脱附曲线和孔径分布

    Figure  4.  Nitrogen adsorption-desorption isotherms and pore width distribution of the three materials

    图  5  不同生物炭材料的FTIR谱图

    Figure  5.  FTIR spectra of different biochar materials

    图  6  2 组非生物阴极硝氮、亚硝氮浓度随时间的变化

    Figure  6.  Variation of nitrate and nitrite concentrations with time in two groups of abiotic cathodes

    图  7  投加3种生物炭材料后生物阴极硝氮、亚硝氮浓度随时间的变化

    注:柱状代表亚硝氮浓度;点状代表硝氮浓度。

    Figure  7.  Variation of nitrate and nitrite concentrations with time in biological cathode under the addition of three biochar materials

    图  8  添加不同生物炭材料时反应器内微生物种群相对丰度

    Figure  8.  Relative abundance of microbial population in reactors with different biochar materials addition

    表  1  3种生物炭材料表面元素含量

    Table  1.   Surface element contents of the three biochar materials % 

    生物炭CNOK
    ABC-80086.886.886.24
    ABC-800N67.6113.2719.12
    ABC-800K76.787.0415.980.2
    下载: 导出CSV

    表  2  投加不同生物炭材料后各组反应器微生物的共有OTU在门水平的相对丰度

    Table  2.   Relative abundance of shared OTU of microorganisms in each reactor at phylum level after different biochar materials addition % 

    细菌门对照组ABC-800ABC-800NABC-800K
    Proteobacteria52.1537.6330.9636.02
    Firmicutes2.634.374.265.38
    Chloroflexi8.329.0011.518.62
    Bacteroidota12.9127.4928.8821.89
    Actinobacteriota3.529.789.337.68
    Synergisteota4.200.300.990.56
    Acidobacteriota0.552.899.084.94
    下载: 导出CSV
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  • 收稿日期:  2021-07-29

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