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Influence of Cathode Modification by Chitosan and Fe^(3+)on the Electrochemical Performance of Marine Sediment Microbial Fuel Cell
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作者 ZAI Xuerong GUO Man +4 位作者 HUANG Xiang ZHANG Huaijing CHEN Yan JI Hongwei FU Yubin 《Journal of Ocean University of China》 SCIE CAS CSCD 2023年第3期709-716,共8页
The electrochemical performances of cathode play a key role in the marine sediment microbial fuel cells(MSMFCs)as a long lasting power source to drive instruments,especially when the dissolved oxygen concentration is ... The electrochemical performances of cathode play a key role in the marine sediment microbial fuel cells(MSMFCs)as a long lasting power source to drive instruments,especially when the dissolved oxygen concentration is very low in seawater.A CTS-Fe^(3+)modified cathode is prepared here by grafting chitosan(CTS)on a carbon fiber surface and then chelating Fe^(3+)through the coordination process.The electrochemical performance in seawater and the output power of the assembled MSMFCs are both studied.The results show that the exchange current densities of CTS and the CTS-Fe^(3+)group are 5.5 and 6.2 times higher than that of the blank group,respectively.The potential of the CTS-Fe^(3+)modified cathode increases by 138 mV.The output power of the fuel cell(613.0 mW m^(-2))assembled with CTS-Fe^(3+)is 54 times larger than that of the blank group(11.4 mW m^(-2))and the current output corresponding with the maximum power output also increases by 56 times.Due to the valence conversion between Fe^(3+)and Fe^(2+)on the modified cathode,the kinetic activity of the dissolved oxygen reduction is accelerated and the depolarization capability of the cathode is enhanced,resulting higher cell power.On the basis of this study,the new cathode materials will be encouraged to design with the complex of iron ion in natural seawater as the catalysis for oxygen reduction to improve the cell power in deep sea. 展开更多
关键词 marine sediments microbial fuel cell chitosan and iron chelation modified cathode electrochemical performance power output
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Pyrolyzed Iron Phthalocyanine-Modified Multi-Walled Carbon Nanotubes as Composite Anode in Marine Sediment Microbial Fuel Cells and Its Electrochemical Performance
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作者 ZAI Xuerong DUAN Zhiwei +2 位作者 CHEN Wei YU Jian FU Yubin 《Journal of Ocean University of China》 SCIE CAS CSCD 2019年第6期1395-1401,共7页
Improving the performance of anode is a crucial step for increasing output power of marine sediment microbial fuel cells(MSMFCs)to drive marine monitor to work for a long term on the ocean floor.A pyrolyzed iron phtha... Improving the performance of anode is a crucial step for increasing output power of marine sediment microbial fuel cells(MSMFCs)to drive marine monitor to work for a long term on the ocean floor.A pyrolyzed iron phthalocyanine modified multi-walled carbon nanotubes composite(FePc/MWCNTs)has been utilized as a novel nodified anode in the MSMFC.Its structure of the composite modified anode and electrochemical performance have been investigated respectively in the paper.There is a substantial improvement in electron-transfer efficiency from the bacteria biofilm to the modified anode via the pyrolyzed FePc/MWCNTs composite based on their cyclic voltammetry(CV)and Tafel curves.The electron transfer kinetic activity of the FePc/MWCNTs-modified anode is 1.86 times higher than of the unmodified anode.The maximum power density of the modified MSMFC was 572.3±14 m W m^-2,which is 2.6 times larger than the unmodified one(218.3±11 m W m^-2).The anodic structure and cell scale would be greatly minimized to obtain the same output power by the modified MSMFC,so that it will make the MSMFC to be easily deployed on the remote ocean floor.Therefore,it would have a great significance for us to design a novel and renewable long term power source.Finally,a novel molecular synergetic mechanism is proposed to elucidate its excellent electrochemical performance. 展开更多
关键词 marine sediment microbial fuel cells iron phthalocyanine/multi-walled carbon NANOTUBE composite MODIFIED anode electrochemical kinetics power density
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3-Aminopropyltriethoxysilane Complexation with Iron Ion Modified Anode in Marine Sediment Microbial Fuel Cells with Enhanced Electrochemical Performance
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作者 ZAI Xuerong GUO Man +6 位作者 HAO Yaokang HOU Shaoxin YANG Zhiwei LI Jia LI Yang JI Hongwei FU Yubin 《Journal of Ocean University of China》 SCIE CAS CSCD 2021年第3期581-589,共9页
Anode modification plays a key role in higher power output in marine sediment microbial fuel cells(MSMFCs).A low-molecular organosilicon compound(3-aminopropyltriethoxysilane)was grafted onto the surface of carbon fel... Anode modification plays a key role in higher power output in marine sediment microbial fuel cells(MSMFCs).A low-molecular organosilicon compound(3-aminopropyltriethoxysilane)was grafted onto the surface of carbon felt using chemical method and a composite modified anode was prepared through organic ligands coordination Fe^(3+)for better electro-chemical per-formance.Results show that the biofilm resistance of the composite modified anode(2707Ω)is 1.3 times greater than that of the unmodified anode(2100Ω),and its biofilm capacitance also increases by 2.2 times,indicating that the composite modification pro-motes the growth and attachment of electroactive bacteria on the anode.Its specific capacitance(887.8 Fm^(−2))is 3.7 times higher than that of unmodified anode,generating a maximum current density of 1.5Am^(−2).In their Tafel curves,the composite modified anodic exchange current density(5.25×10^(−6)Acm^(−2))is 5.8 times bigger than that of unmodified anode,which suggests that the electro-chemical activity of redox,anti-polarization ability and electron transfer kinetic activity are significantly enhanced.The marine sediment microbial fuel cell with the composite modified anode generates the higher power densities than the blank(203.8mWm^(−2) versus 45.07mWm^(−2)),and its current also increases by 4.4 times.The free amino groups on the anode surface expands a creative idea that the modified anode ligates the natural Fe(Ⅲ)ion in sea water in the MSMFCs for its higher power output. 展开更多
关键词 3-AMINOPROPYLTRIETHOXYSILANE iron ion composite modified carbon anode electro-chemical performances marine sediment microbial fuel cells
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二氧化锰晶型对MSMFCs阴极电化学性能的影响
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作者 魏书香 李洋 +2 位作者 钟莲 金顶峰 付玉彬 《电源技术》 CAS 北大核心 2024年第10期1922-1930,共9页
海水环境中较低的阴极催化活性严重限制海泥电池(MSMFCs)长期输出功率。碳毡阴极经二氧化锰(MnO_(2))改性可显著提高海泥电池阴极溶氧还原动力学和电化学性能,进而提升电池输出功率。利用水热法合成4种晶型(α、β、γ和δ)MnO_(2)用于... 海水环境中较低的阴极催化活性严重限制海泥电池(MSMFCs)长期输出功率。碳毡阴极经二氧化锰(MnO_(2))改性可显著提高海泥电池阴极溶氧还原动力学和电化学性能,进而提升电池输出功率。利用水热法合成4种晶型(α、β、γ和δ)MnO_(2)用于海泥电池阴极改性,研究了4种晶型MnO_(2)对海泥电池阴极电化学性能的影响并进行了机理分析。结果表明,与空白对照组相比,4种晶型MnO_(2)均可显著提高阴极抗极化性能、电容性能、交换电流密度和最大输出功率;其中,β-MnO_(2)由于具有高浓度的Mn3+和氧空位,大幅提高了阴极氧还原活性和电化学性能,使比电容最高达846.08 F/m^(2),功率密度最高达700.2 mW/m^(2)。该结果有利于促进设计低溶氧海水条件下海泥电池阴极,进而开发高功率海底原位电源。 展开更多
关键词 海底沉积物微生物燃料电池 二氧化锰 晶型 阴极改性 电化学性能 输出功率
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Humic Acid and Iron Chelation Modified Anode Improves the Electrochemical Performance of Marine Sediment Microbial Fuel Cell
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作者 FU Yubin CHEN Jiaqi +4 位作者 CHEN Yan HUANG Xiang LI Yang ZHANG Huaijing ZAI Xuerong 《Journal of Ocean University of China》 SCIE CAS CSCD 2022年第2期388-394,共7页
Marine sediment microbial fuel cell(MSMFCs)can be utilized as a long lasting power source to drive small instruments to work for long time on ocean floor and its higher power has a significant meaning for practical ap... Marine sediment microbial fuel cell(MSMFCs)can be utilized as a long lasting power source to drive small instruments to work for long time on ocean floor and its higher power has a significant meaning for practical application.Anode modification can greatly improve the performance of MSMFCs.Herein,humic acid(HA)and humic acid-iron ion complex(HA-Fe)were used to modify the anode for constructing a better MSMFCs.The results indicated that HA-Fe modified anode,better than HA modification,significantly improved the MSMFCs cell power output.The maximum power density of HA-Fe modified MSMFCs is 165.3 mW m−2,which are 6.5-folds of blank MSMFCs.The number of microorganisms on anode,redox activity,and relative kinetic activity were 1.8-,6.1-,and 13.1-folds of blank MSMFCs,respectively.The MSMFCs improvement would be attributed to the electron transfer media of HA and the valence conversion of Fe ions.A synergistic interaction between the naturally occurring HA and Fe ions on the anodic surface in marine sediments would make the modified anodes have‘renewable’characteristics,which is beneficial for the MSMFCs to maintain its long-term higher power. 展开更多
关键词 marine sediment microbial fuel cells humic acid and iron complex modified anode electrochemical performance
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Application of interface material and effects of oxygen gradient on the performance of single-chamber sediment microbial fuel cells(SSMFCs)
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作者 Chin-Tsan Wang Thangavel Sangeetha +5 位作者 Wei-Mon Yan Wen-Tong Chong Lip-Huat Saw Feng Zhao Chung-Ta Chang Chen-Hao Wang 《Journal of Environmental Sciences》 SCIE EI CAS CSCD 2019年第1期163-168,共6页
Single-chamber sediment microbial fuel cells(SSMFCs) have received considerable attention nowadays because of their unique dual-functionality of power generation and enhancement of wastewater treatment performance. Th... Single-chamber sediment microbial fuel cells(SSMFCs) have received considerable attention nowadays because of their unique dual-functionality of power generation and enhancement of wastewater treatment performance. Thus, scaling up or upgrading SSMFCs for enhanced and efficient performance is a highly crucial task. Therefore, in order to achieve this goal, an innovative physical technique of using interface layers with four different pore sizes embedded in the middle of SSMFCs was utilized in this study.Experimental results showed that the performance of SSMFCs employing an interface layer was improved regardless of the pore size of the interface material, compared to those without such layers. The use of an interface layer resulted in a positive and significant effect on the performance of SSMFCs because of the effective prevention of oxygen diffusion from the cathode to the anode. Nevertheless, when a smaller pore size interface was utilized, better power performance and COD degradation were observed. A maximum power density of 0.032 mW/m^2 and COD degradation of 47.3% were obtained in the case of an interface pore size of 0.28 μm. The findings in this study are of significance to promote the future practical application of SSMFCs in wastewater treatment plants. 展开更多
关键词 Single sediment microbial fuel cells INTERFACE layer Dissolved OXYGEN PORE size OXYGEN DIFFUSION DIFFUSION coefficient
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海泥孔隙率对海底微生物燃料电池电化学性能影响及有机质扩散分析
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作者 李洋 刘志 +5 位作者 宰学荣 黄翔 陈岩 曹亚俐 张怀静 付玉彬 《上海交通大学学报》 EI CAS CSCD 北大核心 2024年第10期1567-1574,I0003,共9页
海底沉积物微生物燃料电池(MSMFC)在长期运行过程中,海泥孔隙率影响阳极表面水平方向有机质扩散,进而影响阳极电化学性能和电池功率输出.通过人工调节孔隙率在实验室模拟并研究孔隙率对MSMFC的影响,建立孔隙率与MSMFC产电量和水平扩散... 海底沉积物微生物燃料电池(MSMFC)在长期运行过程中,海泥孔隙率影响阳极表面水平方向有机质扩散,进而影响阳极电化学性能和电池功率输出.通过人工调节孔隙率在实验室模拟并研究孔隙率对MSMFC的影响,建立孔隙率与MSMFC产电量和水平扩散系数之间定量关系式.结果表明:随着孔隙率升高,阳极动力学活性先降低后升高,最高动力学活性是最低动力学活性的3.85倍;电池最大输出功率密度在孔隙率为45.2%时,达到最大值206.8 mW/m^(2).随着孔隙率的增大,有机质水平扩散系数升高,并与MSMFC产电量存在线性关系.当孔隙率为45.2%时,扩散系数为0.48 m^(2)/s,MSMFC产电量达到804.04 J.该研究结果将为MSMFC在不同海域布放选址、阳极结构设计及电池长期产电运行提供技术支撑. 展开更多
关键词 海泥孔隙率 海底微生物燃料电池 电化学特性 电池功率 稳态扩散 有机质水平扩散系数
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产电微生物对SMFC产电及降解性能的影响
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作者 高洁 唐善法 程远鹏 《石油与天然气化工》 CAS CSCD 北大核心 2024年第1期123-128,共6页
目的在以含油污泥为阳极底泥的沉积型微生物燃料电池(SMFC)体系中,通过改变产电微生物种类和分布方式,探究产电微生物对SMFC产电及降解性能的影响。方法通过采集输出电压、功率密度、表观内阻来检测石油去除率,比较了不同单菌-SMFC、不... 目的在以含油污泥为阳极底泥的沉积型微生物燃料电池(SMFC)体系中,通过改变产电微生物种类和分布方式,探究产电微生物对SMFC产电及降解性能的影响。方法通过采集输出电压、功率密度、表观内阻来检测石油去除率,比较了不同单菌-SMFC、不同混合菌-SMFC的产电性能和降解性能,考查了菌种分布对SMFC性能的影响。结果在单菌-SMFC中,弗氏柠檬酸杆菌-SMFC的产电及降解性能均优于其他5种单菌构筑的SMFC;混合菌-SMFC的产电及降解性能较单菌-SMFC有较大提升,且其中蜡样芽孢杆菌+中间苍白杆菌-SMFC的产电及降解性能最优,输出电压可达到515.30 mV;菌种分布在阳极材料中和阳极底泥中都可以降解含油污泥中的有机物,但是菌种分布在阳极材料中更有利于SMFC产电性能及降解性能的发挥。结论混合菌相对于单菌能够显著提升SMFC的产电及降解性能,而且菌种分布在阳极材料中更有益于SMFC产电性能及降解性能的发挥。 展开更多
关键词 沉积型微生物燃料电池 含油污泥 产电微生物 单菌 混合菌 菌种分布
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3种沉水植物-沉积型微生物燃料电池对黑臭水体修复的研究
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作者 赵亚楠 毛羽丰 王剑 《广东化工》 CAS 2024年第18期127-129,158,共4页
沉水植物-沉积型微生物燃料电池(Submerged plantsediment microbialfuelcell,SP-SMFC)是目前解决修复水体复黑臭最有发展前景的技术之一。以黑臭水体底泥为底质,构建了3种不同的沉水植物与沉积型微生物燃料电池耦合系统:分别为篦齿眼子... 沉水植物-沉积型微生物燃料电池(Submerged plantsediment microbialfuelcell,SP-SMFC)是目前解决修复水体复黑臭最有发展前景的技术之一。以黑臭水体底泥为底质,构建了3种不同的沉水植物与沉积型微生物燃料电池耦合系统:分别为篦齿眼子菜-沉积型微生物燃料电池(标记为SP-SMFC1)、矮生苦草-沉积型微生物燃料电池(标记为SP-SMFC2)和金鱼藻-沉积型微生物燃料电池(标记为SP-SMFC3),为对照还构建了无植物的对照组(标记为SMFC)。结果表明:所构建的实验系统经驯化后能够稳定运行;引入沉水植物可提高系统输出电压,其中SP-SMFC2系统平均最高输出电压最大为0.659V;各实验组对底泥和上覆水的有机质和氮磷去除效果明显;构筑的系统可以有效防止水体复黑臭的发生。 展开更多
关键词 沉水植物 沉积物微生物燃料电池 输出电压 底泥修复 上覆水
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SMFC用于湖泊底泥处理及影响因素的研究进展
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作者 陈利争 李小亚 +2 位作者 付时翔 钟焕 王志鑫 《现代化工》 CAS CSCD 北大核心 2024年第8期60-63,68,共5页
介绍了沉积物微生物燃料电池(SMFC)的运行机理,阐述了SMFC用于湖泊底泥污染物(有机质、氮磷、重金属及有机污染物等)去除过程机理及效果,分析了影响SMFC系统处理效能及产电性能的重要因素(电极材料及距离、微生物种类及丰度、pH及DO等)... 介绍了沉积物微生物燃料电池(SMFC)的运行机理,阐述了SMFC用于湖泊底泥污染物(有机质、氮磷、重金属及有机污染物等)去除过程机理及效果,分析了影响SMFC系统处理效能及产电性能的重要因素(电极材料及距离、微生物种类及丰度、pH及DO等),以期更好地将SMFC应用于实际工程。 展开更多
关键词 沉积物微生物燃料电池 湖泊底泥 污染物质 影响因素
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湖泊底泥微生物燃料电池中磷形态分布及释放研究 被引量:1
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作者 张广毅 张嘉涛 王晓伟 《生态环境学报》 CSCD 北大核心 2023年第3期590-598,共9页
针对沉积物中沉积磷(P)通过微生物活动再释放,致使湖泊富营养化反复的问题,采集郑州大学眉湖上覆水和沉积物,搭建一个沉积式微生物燃料电池(Sediment Microbial Fuel Cell,SMFC)系统,研究了通过SMFC限制沉积磷向上覆水体释放的方法。实... 针对沉积物中沉积磷(P)通过微生物活动再释放,致使湖泊富营养化反复的问题,采集郑州大学眉湖上覆水和沉积物,搭建一个沉积式微生物燃料电池(Sediment Microbial Fuel Cell,SMFC)系统,研究了通过SMFC限制沉积磷向上覆水体释放的方法。实验周期内监测SMFC的电压和阳极电极电位、上覆水温度pH、沉积物磷的Standards Measurements and Testing(SMT)法分级提取;并在实验开始与结束收集阳极微生物样进行微生物群落及基因分析;首次使用氧化锆薄膜扩散梯度技术(Zr-Oxide Diffusive Gradients in Thin-films,Zr-Oxide DGT)可视化了SMFC沉积物中不稳定磷亚毫米分辨率的浓度分布。结果表明:SMFC阳极电极电位从-100 mV升至230 mV;上覆水pH从7.15升至7.46;SMFC沉积物烧失量(Loss on Ignition,LOI)从18.31%±0.7%降至13.09%±1.10%,低于对照组的14.29%±2.10%;SMFC显著促进了孔隙水磷向沉积物磷的矿化过程,在沉积物垂向方向上,Na OH-P和HCl-P出现了明显的区域性增加;根据沉积物DGT磷的二维(2D)图像,SMFC使沉积物DGT磷的浓度最低降至初始值的66%;基于京都基因与基因组百科全书(Kyoto Encyclopedia of Genes and Genomes,KEGG)数据库的功能基因分析,SMFC使磷相关功能基因丰度显著增加。证明SMFC对于沉积物磷和水相磷分布有显著影响,通过基质竞争、提高阳极电位等方式减弱固相磷的溶解,促进水相磷向沉积相磷的转化,可用于富营养化水体原位底泥磷稳定化。该文深入研究了SMFC固磷作用机理,为修复水体内源磷污染提供了一种新思路。 展开更多
关键词 沉积物微生物燃料电池 薄膜梯度扩散技术 标准测量测试方法(SMT法) 京都基因与基因组百科全书
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水生植物-沉积物微生物燃料电池修复黑臭水 被引量:4
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作者 潘晶 王诗尧 +4 位作者 孟雨欣 张钰茜 李梓琪 范琳琳 李琳 《沈阳师范大学学报(自然科学版)》 CAS 2023年第2期173-179,共7页
水生植物-沉积物微生物燃料电池(aquatic plant sediment microbial fuel cell,AP-SMFC)是解决当前环境问题及能源短缺的最有发展前景的技术之一。以黑臭水体底泥为底质,构建了芦苇-沉积物微生物燃料电池(标记为APSM1)、美人蕉-沉积物... 水生植物-沉积物微生物燃料电池(aquatic plant sediment microbial fuel cell,AP-SMFC)是解决当前环境问题及能源短缺的最有发展前景的技术之一。以黑臭水体底泥为底质,构建了芦苇-沉积物微生物燃料电池(标记为APSM1)、美人蕉-沉积物微生物燃料电池(标记为APSM2)和无植物的沉积物微生物燃料电池(标记为SM)共3个实验系统,研究了3个系统沉积物微生物燃料电池的产电特性及对上覆水和底泥的修复效果。结果表明:APSM1,APSM2和SM启动期为8 d;3个实验系统启动结束后均能维持较稳定的产电,输出电压、电流密度和功率密度顺序为APSM1>APSM2>SM。APSM1和APSM2对上覆水化学需氧量(chemical oxygen demand,COD)、氨氮(ammonia nitrogen,NH+4-N)、总磷(total phosphorus,TP)的平均去除率分别为84.3%和81.6%,82.7%和79.3%,85.5%和83.4%,并且显著高于SM。APSM1,APSM2和SM对底泥中的有机质、NH+4-N和总氮(total nitrogen,TN)去除率分别高于80.5%,49.4%和49.2%,3个实验系统间没有显著差异。APSM1和APSM2对底泥中TP的平均去除率分别为72.6%和66.4%,显著高于SM(42.6%)。APSM1,APSM2和SM对底泥中As,Pb的去除率均高于79%,各系统之间没有显著差异;对底泥中Zn,Cr和Cu的去除率均高于80%,显著高于SM(<61%)。芦苇和美人蕉的引入提升了沉积物微生物燃料电池系统的产电性能,增强了系统对上覆水中COD,NH+4-N,TP及底泥中TP,Zn,Cr和Cu的去除效果。 展开更多
关键词 植物 沉积物微生物燃料电池 产电 修复
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Enhanced nitrate reduction in water by a combined bio-electrochemical system of microbial fuel cells and submerged aquatic plant Ceratophyllum demersum 被引量:5
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作者 Peng Xu Enrong Xiao +3 位作者 Junmei Wu Feng He Yi Zhang Zhenbin Wu 《Journal of Environmental Sciences》 SCIE EI CAS CSCD 2019年第4期338-351,共14页
High nitrate(NO_3^-)loading in water bodies is a crucial factor inducing the eutrophication of lakes.We tried to enhance NO_3^-reduction in overlying water by coupling sediment microbial fuel cells(SMFCs)with submerge... High nitrate(NO_3^-)loading in water bodies is a crucial factor inducing the eutrophication of lakes.We tried to enhance NO_3^-reduction in overlying water by coupling sediment microbial fuel cells(SMFCs)with submerged aquatic plant Ceratophyllum demersum.A comparative study was conducted by setting four treatments:open-circuit SMFC(Control),closed-circuit SMFC(SMFC-c),open-circuit SMFC with C.demersum(Plant),and closed-circuit SMFC with C.demersum(P-SMFC-c).The electrochemical parameters were documented to illustrate the bio-electrochemical characteristics of SMFC-c and P-SMFC-c.Removal pathways of NO_3^- in different treatments were studied by adding quantitative^(15)NO_3^- to water column.The results showed that the cathodic reaction in SMFC-c was mainly catalyzed by aerobic organisms attached on the cathode,including algae,Pseudomonas,Bacillus,and Albidiferax.The oxygen secreted by plants significantly improved the power generation of SMFC-c.Both electrogenesis and plants enhanced the complete removal of NO_3^- from the sediment–water system.The complete removal rates of added^(15)N increased by 17.6% and 10.2% for SMFC-c and plant,respectively,when compared with control at the end of experiment.The electrochemical/heterotrophic and aerobic denitrification on cathodes mainly drove the higher reduction of NO_3^- in SMFC-c and plant,respectively.The coexistence of electrogenesis and plants further increased the complete removal of NO_3^- with a rate of 23.1%.The heterotrophic and aerobic denitrifications were simultaneously promoted with a highest abundance of Flavobacterium,Bacillus,Geobacter,Pseudomonas,Rhodobacter,and Arenimonas on the cathode. 展开更多
关键词 sediment microbial fuel cells(smfcs) Ceratophyllum demersum Power generation Nitrate(NO3-) REMOVAL Stable N ISOTOPIC REMOVAL mechanisms
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Sediment microbial fuel cell with floating biocathode for organic removal and energy recovery 被引量:4
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作者 Aijie WANG Haoyi CHENG +3 位作者 Nanqi REN Dan CUI Na LIN Weimin WU 《Frontiers of Environmental Science & Engineering》 SCIE EI CAS CSCD 2012年第4期569-574,共6页
A sediment microbial fuel cell (SMFC) with three dimensional floating biocathode (FBC) was developed for the electricity generation and biodegradation of sediment organic matter in order to avoid negative effect o... A sediment microbial fuel cell (SMFC) with three dimensional floating biocathode (FBC) was developed for the electricity generation and biodegradation of sediment organic matter in order to avoid negative effect of dissolved oxygen (DO) depletion in aqueous environments on cathode performance and search cost-effective cathode materials. The biocathode was made from graphite granules with microbial attachment to replace platinum (Pt)-coated carbon paper cathode in a laboratory-scale SMFC (3 L in volume) filled with river sediment (organic content 49±4 g. kg^-1 dry weight). After start-up of 10 days, the maximum power density of 1.00W.m^-3 (based on anode volume) was achieved. The biocathode was better than carbon paper cathode catalyzed by Pt. The attached biofilm on cathode enhanced power generation significantly. The FBC enhanced SMFC performance further in the presence aeration. The SMFC was continuously operated for an over 120-day period. Power generation peaked within 24 days, declined gradually and stabilized at a level of 1/6 peak power output. At the end, the sediment organic matter content near the anode was removed by 29% and the total electricity generated was equal to 0.251 g of chemical oxygen demand (COD) removed. 展开更多
关键词 microbial fuel cell (MFC) sediment BIOCATHODE electricity generation organic removal
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水生植物-沉积物微生物燃料电池研究进展
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作者 潘晶 范琳琳 +4 位作者 王诗尧 李梓琪 陈晶娜 姜泽芳 王蕾 《沈阳师范大学学报(自然科学版)》 CAS 2023年第4期378-384,共7页
水生植物-沉积物微生物燃料电池是将水生植物引入沉积物环境体系中,利用水生植物光合作用、呼吸作用及微生物新陈代谢作用,将有机污染物中蕴含的化学能转化成电能的装置,能够实现“污水净化”和“能量回收”的双重作用,具有显著的经济... 水生植物-沉积物微生物燃料电池是将水生植物引入沉积物环境体系中,利用水生植物光合作用、呼吸作用及微生物新陈代谢作用,将有机污染物中蕴含的化学能转化成电能的装置,能够实现“污水净化”和“能量回收”的双重作用,具有显著的经济效益和环境效益。详细介绍了水生植物-沉积物微生物燃料电池的产电原理,阐述了电极、外电阻、微生物、电子中介体、水生植物等电池内部结构及温度、溶解氧浓度、沉积物中有机物等电池外部环境对其产电和去污的影响,同时对水生植物-沉积物微生物燃料电池面临的挑战、发展趋势进行了展望,以期为该技术的实际应用提供理论参考。 展开更多
关键词 水生植物-沉积物微生物燃料电池 产电原理 电池结构 外部环境
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不同湿地植物构建植物沉积型微生物燃料电池的研究 被引量:7
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作者 吴夏芫 宋天顺 +2 位作者 朱旭君 周楚新 韦萍 《可再生能源》 CAS 北大核心 2013年第9期78-82,共5页
考察了粉黛万年青、小白掌、金边富贵竹、鹅掌柴4种湿地植物构建植物沉积型微生物燃料电池(Plant-Sediment Microbial Fuel Cell,Plant-SMFC)对电池基础特性的影响。试验结果表明:粉黛万年青、小白掌、金边富贵竹均可用来构建Plant-SMFC... 考察了粉黛万年青、小白掌、金边富贵竹、鹅掌柴4种湿地植物构建植物沉积型微生物燃料电池(Plant-Sediment Microbial Fuel Cell,Plant-SMFC)对电池基础特性的影响。试验结果表明:粉黛万年青、小白掌、金边富贵竹均可用来构建Plant-SMFC,并能显著提高SMFC的产电性能,其中小白掌电池组产电性能最优,Pmax为14.0 mW/m2,是空白的2.5倍。鹅掌柴在电池运行过程中烂根,不适合构建Plant-SMFC。阴阳极电极电位分析表明,各电池组输出电压的差异主要在于阳极电位的变化不同,而阴极电位变化基本一致且均在后期产生了一个大的跃迁,采用LSV验证了该跃迁的原因。最后利用HPLC分析证明了根系分泌有机酸的种类及含量与产电水平成正比,其中小白掌分泌有机酸种类及含量最多,有机酸总量达1.292 mg。 展开更多
关键词 沉积型微生物燃料电池 植物 生物阴极 根系分泌物
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沉积物微生物燃料电池修复水体沉积物研究进展 被引量:16
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作者 宋天顺 晏再生 +1 位作者 胡颖 江和龙 《现代化工》 CAS CSCD 北大核心 2009年第11期15-19,共5页
沉积物微生物燃料电池在修复水体沉积物的研究近年来受到广泛关注。相比较传统的原位生物修复技术,其不需要投加电子受体或供氧剂,而是以电极作为电子受体,并可在氧化有机物的同时产生一定的电能。本文详细介绍了其工作原理和特点,并阐... 沉积物微生物燃料电池在修复水体沉积物的研究近年来受到广泛关注。相比较传统的原位生物修复技术,其不需要投加电子受体或供氧剂,而是以电极作为电子受体,并可在氧化有机物的同时产生一定的电能。本文详细介绍了其工作原理和特点,并阐述了阴极、阳极、电极间距、溶解氧浓度、外电阻、底物传质、微生物、水体种类对其的影响,对今后的应用和研发重点进行了展望。 展开更多
关键词 微生物燃料电池 沉积物 修复
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MnO_2-r-GO修饰阴极对沉积型微生物燃料电池(MFC)产电性能的影响 被引量:6
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作者 潘丹云 任月萍 +3 位作者 付飞 赵亚楠 秦世忠 李秀芬 《环境化学》 CAS CSCD 北大核心 2013年第4期531-536,共6页
考察了MnO2-石墨烯(r-GO)修饰阴极对沉积型微生物燃料电池(SMFC)的产电性能和体系有机质去除率的影响.实验结果表明,采用MnO2和r-GO对SMFC阴极进行复合修饰,运行稳定后,MnO2-r-GO修饰阴极体系与空白阴极体系相比,最高产电电压从65.2 mV... 考察了MnO2-石墨烯(r-GO)修饰阴极对沉积型微生物燃料电池(SMFC)的产电性能和体系有机质去除率的影响.实验结果表明,采用MnO2和r-GO对SMFC阴极进行复合修饰,运行稳定后,MnO2-r-GO修饰阴极体系与空白阴极体系相比,最高产电电压从65.2 mV增大到325.7 mV;最大功率密度由0.28 mW.m-2增大到17.4 mW.m-2,并且体系的内阻由1157Ω显著降低到159Ω;空白阴极体系和MnO2-r-GO修饰阴极体系的COD去除率和氨氮(NH4+-N)去除率分别由25.8%和27.3%增大到37.0%和32.7%. 展开更多
关键词 沉积型微生物燃料电池(SMFC) 阴极修饰 二氧化锰(MnO2) 石墨烯(r-GO)
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海底生物燃料电池作为电源驱动小型电子器件的应用研究 被引量:16
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作者 付玉彬 李建海 +1 位作者 赵仲凯 徐谦 《中国海洋大学学报(自然科学版)》 CAS CSCD 北大核心 2012年第6期93-98,共6页
海底沉积物生物燃料电池(简称海底生物燃料电池)是一种新型的海洋能源材料电池,它的发电机理主要是利用海底沉积层内细菌代谢产生电子,通过人工放置的改性阳极收集电子,产生电能,可用于驱动水下监测仪器的长期连续运行。本研究首先设计... 海底沉积物生物燃料电池(简称海底生物燃料电池)是一种新型的海洋能源材料电池,它的发电机理主要是利用海底沉积层内细菌代谢产生电子,通过人工放置的改性阳极收集电子,产生电能,可用于驱动水下监测仪器的长期连续运行。本研究首先设计海底生物燃料电池实验室装置,利用电池串联升压的方式,实现其驱动小型电子装置和监测仪器的连续运行。在此基础上,设计并安装了实际海况电池实验装置,利用并联设计和特殊升压装置,在胶州湾浅海成功驱动小型电子装置的运行。本研究初步验证了海底生物燃料电池作为电源驱动仪器的可行性。 展开更多
关键词 海底沉积层 生物燃料电池 电源供给 小型电子器件 持续工作
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植物沉积型微生物燃料电池的基础研究 被引量:3
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作者 吴夏芫 宋天顺 +2 位作者 朱旭君 周楚新 韦萍 《南京工业大学学报(自然科学版)》 CAS 北大核心 2013年第6期91-96,共6页
以湿地植物仙羽蔓绿绒构建植物沉积型微生物燃料电池(Plant-SMFC),分别考察阳极不同驯化方式及电极材料对电池基础特性的影响。结果表明:Plant-SMFC以阳极协同驯化方式富集产电菌时,电池启动期较自然驯化方式缩短了3 d,产电水平亦明显提... 以湿地植物仙羽蔓绿绒构建植物沉积型微生物燃料电池(Plant-SMFC),分别考察阳极不同驯化方式及电极材料对电池基础特性的影响。结果表明:Plant-SMFC以阳极协同驯化方式富集产电菌时,电池启动期较自然驯化方式缩短了3 d,产电水平亦明显提高,最大输出功率密度(2.84 mW/m2)为自然驯化方式的3.2倍,且该驯化方式对植物生长影响不大;活性炭纤维毡作为阳极电极材料效果优于石墨毡,电池启动期缩短了8 d,最大输出功率密度(5.78 mW/m2)提高了1倍,同时更利于植物的生长繁殖,运行60 d后收获植物干质量为2.5 g;高效液相色谱(HPLC)分析证明仙羽蔓绿绒根系分泌物中有机酸主要为顺丁烯二酸、反丁烯二酸、柠檬酸等小分子有机酸,它们均易被阳极产电菌利用以维持电池的稳定产电。 展开更多
关键词 沉积型微生物燃料电池 驯化 阳极材料 根系分泌物
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