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JOURNAL ARTICLES |
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2022 |
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106. Noori M. T., Thatikayala D., Pant D., Min, B. A critical review on microbe-electrode |
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interactions towards heavy metal ion detection using microbial fuel cell technology. Bioresource Technology, 126589. |
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105. Vu M. T., Thatikayala D., Min B. Porous reduced-graphene oxide supported hollow titania |
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(rGO/TiO2) as an effective catalyst for upgrading electromethanogenesis. International Journal of Hydrogen Energy, 47(2), 1121-1131. |
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104. Reddy C. N., Kondaveeti S., Mohanakrishna G., Min, B. Application of bioelectrochemical |
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systems to regulate and accelerate the anaerobic digestion processes. Chemosphere, 287, 132299. |
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2021 |
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103. Pu K. B., Zhang K., Guo K., Min B., Chen Q. Y., Wang Y. H. Firmly coating carbon |
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nanoparticles onto titanium as high performance anodes in microbial fuel cells. Electrochimica Acta, 399, 139416. |
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102. Thatikayala D., Min B. Ginkgo leaves extract-assisted synthesis of ZnO/CuO nanocrystals for |
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efficient UV-induced photodegradation of organic dyes and antibacterial activity. Journal of Materials Science: Materials in Electronics, 32(13), 17154-17169. |
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101. Noori M. T., Mohan S. V., Min B. Microbial electrosynthesis of multi-carbon volatile fatty |
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acids under the influence of different imposed potentials. Sustainable Energy Technologies and Assessments, 45, 101118. |
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100. Thatikayala D., Pant D., Min B. MnO2/reduced graphene oxide nanohybrids as a cathode |
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catalyst for the microbial reduction of CO2 to acetate and isobutyric acid. Sustainable Energy Technologies and Assessments, 45, 101114. |
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99. Thatikayala D., Min B. Copper ferrite supported reduced graphene oxide as cathode materials |
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to enhance microbial electrosynthesis of volatile fatty acids from CO2. Science of The Total Environment, 768, 144477. |
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98. Reddy C. N., Kondaveeti S., Min B. Influence of Trace Metals concentration on Methane |
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generation using Microbial Electrochemical Systems. Process Biochemistry, 102, 213-219. |
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97. Thatikayala D., Pant D., Min B. A mesoporous silica-supported CeO 2/cellulose cathode |
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catalyst for efficient bioelectrochemical reduction of inorganic carbon to biofuels. Reaction Chemistry & Engineering, 6(10), 1993-2001. |
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2020 |
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96. Nguyen H.T.H., Min B. Using multiple carbon brush cathode in a novel tubular photosynthetic microbial |
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fuel cell for enhancing bioenergy generation and advanced wastewater treatment. Bioresource Technology. 316 |
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95. Zambrano J., Park H., Min B. Enhancing electrochemical degradation of phenol at optimum pH condition |
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with a Pt/Ti anode electrode. Environmental Technology. 41:3248 – 3259 |
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94. Thatikayala D., Ponnamma D., Sadasivuni K.K., Cabibihan J.J., Al-Ali A.K., Malik R.A., Min B. |
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Progress of Advanced Nanomaterials in the Non-Enzymatic Electrochemical Sensing of Glucose and H2O2. Biosensors. 10 |
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93. Vu M.T., Noori Md.T., Min B. Magetite/Zeolite nanocomposite-modified cathode for enhancing methane |
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generation in microbial electrochemical systems. Chemical Engineeing Journal. 393 |
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92. Noori Md.T., Vu M.T., Ali R.B., Min B. Recent advances in cathode materials and configurations |
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for upgrading methane in bioelectrochemical systems integrated with anaerobic digestion. Chemical Engineering Journal. 392 |
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91. Lee M., Kondaveeti S., Jeon T., Kim I., Min B. Influence of Humidity on Performance of Single Chamber |
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Air-Cathode Microbial Fuel Cells with Different Separators. Processes. 8 |
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90. Nguyen H.T.H., Min B. Leachate treatment and electricity generation using an algae-cathode microbial |
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fuel cell with continuous flow through the chambers in series. Science of the Total Environment. 723 |
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89. Li S., Song Y., Baek J., Im H., Sakuntala M., Kim M., Park C., Min B., Kim J. Bioelectrosynthetic |
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Conversion of CO2 Using Different Redox Mediators : Electron and Carbon Balances in a Bioelectrochemical System. Energies. 13 |
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88. Zambrano J., Min B. Electrochemical treatment of leachate containing highly concentrated phenol and |
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ammonia using a Pt/Ti anode at different current densities. Environmental Technology & Innovation. 18 |
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87. Modestra J.A., Reddy C.N., Krishna K.V., Min B., Mohan S.V. Regulated surface potential impacts |
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bioelectrogenic activity, interfacial electron transfer and microbial dynamics in microbial fuel cell. Renewable Energy. 149 |
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86. Hemalatha M., Sravan J.S., Min B., Mohan S.V. Concomitant use of Azolla derived bioelectrode as anode |
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and hydrolysate as substrate for microbial fuel cell and elecro-fermentation applications. Science of the Total Environment. 707 |
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85. Flores-Rodriguez C., Min B. Enrichmet of specific microbial communities by optimum applied voltages |
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for enhanced methane production by microbial electrosynthesis in anaerobic digestion. Bioresource Technology. 300 |
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84. Kondaveeti S., Lee S., Park H., Min B. Specific enrichment of different Geobacter sp. in anode biofilm |
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by varying interspatial distance of electrodes in air-cathode microbial fuel cell (MFC). Electrochimica Acta. 331 |
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83. Vu M.T., Noori Md.T., Min B. Conductive magnetite nanoparticles trigger syntrophic methane production |
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in single chamber microbial electrochemical systems. Bioresource Technology. 296 |
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82. Kumar A.N., Chatterjee S., Hemalatha M., Althuri A., Min B., Kim S., Mohan S.V. Deoiled algal biomass |
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derived renewable sugars for bioethanol and biopolymer production in biorefinery framework. Bioresource Technology. 296 |
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2019 |
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81. Gavilanes J., Noori Md.T., Min B. Enhancing bioalcohol production from volatile fatty acids |
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by suppressing methanogenic activity in single chamber microbial electrosynthesis cells. Bioresource Technology. 7 |
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80. Lee M., Reddy C.N., Min B. In situ integration of microbial electrochemical systems into anaerobic |
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digestion to improve methane fermentation at different substrate concentrations. International Journal of Hydrogen Energy. 44:2380 – 2389 |
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79. El-Dalatony M.M., Salama El.S., Kurade M.B., Kim K., Govindwar S.P., Kim J., Kwon E.E., |
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Min B., Jang M., Oh S., Chang S., Jeon B. Whole conversion of microalgal biomass biomass into biofuels through successive high-throughput fermentation. Chemical Engineering Journal. 360: 797 – 805 |
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78. Gavilanes J., Reddy C.N., Min B. Microbial Electrosynthesis of Bioalcohols through Reduction |
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of High Concentrations of Volatile Fatty Acids. Energy and Fuels. 33:4264 – 4271 |
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77. Vu H.T., Min B. Integration of submersible microbial fuel cell in anaerobic digestion for enhanced |
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production of methane and current at varying glucose levels. International Journal of Hydrogen Energy. 44:7574 – 7582 |
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76. Kakarla R., Min B. Sustainable electricity generation and ammonium removal by microbial fuel cell |
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with a microalgae assisted cathode at various environmental conditions. Bioresource technology. 284:161 – 167 |
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75. Hemalatha M., Sravan J.S., Min B., Mohan S.V. Microalgae-biorefinery with cascading resource |
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recovery design associated to dairy wastewater treatment. Bioresource Technology. 284:424 – 429 |
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74. Lee M., Kakarla R., Min B. Performance of an air-cathode microbial fuel cell under varied relative |
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humidity conditions in the cathode chamber. Bioprocess and Biosystems Engineering. 42:1247 – 1254 |
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73. Zambrano J., Min B. Comparison on efficiency of electrochemical phenol oxidation in two different |
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supporting electrolytes (NaCl and Na 2 SO 4 ) using Pt/Ti electrode. Environmental Technology and Innovation. 15 |
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72. Flores-Rodriguez C., Reddy C.N., Min B. Enhanced methane production from acetate intermediate |
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by bioelectrochemical anaerobic digestion at optimal applied voltages. Biomass and Bioenergy. 127 |
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71. Reddy C.N., Bae S.W., Min B. Biological removal of H 2 S gas in a semi-pilot scale biotrickling filter : |
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Optimization of various parameters for efficient removal at high loading rates and low pH conditions. Bioresource Technology. 285 |
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70. Vu H.T., Min B. Enhanced methane fermentation of municipal sewage sludge by microbial |
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electrochemical systems integrated with anaerobic digestion. International Journal of Hydrogen Energy. 44:30357 – 30366 |
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69. Noori Md.T., Tiwari B.R., Ghangrekar M.M., Min B. Azadirachta indica leaf-extract-assisted synthesis |
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of CoO-NiO mixed metal oxide for application in a microbial fuel cell as a cathode catalyst. Sustainable Energy and Fuels. 3:3430 – 3440 |
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68. Reddy C.N., Nguyen H.T.H., Noori Md.T., Min B. Potential applications of algae in the cathode |
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of microbial fuel cells for enhanced electricity generation with simultaneous nutrient removal and algae biorefinery: Current status and future perspectives. Bioresource Technology. 292 |
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67. Noori Md.T., Min B. Highly porous FexMnOy (x=1, 2 and y=3,4) microsphere as an efficient cathode |
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catalyst for microbial electrosynthesis of volatile fatty acids from CO2. ChemElectroChem. 6 : 5973 – 5983 |
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66. Kondaveeti S., Kang E., Liu H., Min B. Continuous autotrophic denitrification process |
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for treating ammonium-rich leachate wastewater in bioelectrochemical denitrification system (BEDS). Bioelectrochemistry. 130 |
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65. Noori Md.T., Ghangrekar M.M., Mukherjee C.K., Min B. Biofouling effects on the performance |
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of microbial fuel cells and recent advances in biotechnological and chemical strategies for mitigation. Biotechnology Advances. 37 |
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64. Hoai Thi Vu., Min B. Integration of submersible microbial fuel cell in anaerobic digestion for enhanced |
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production of methane and current at varying glucose levels. International journal of Hydrogen Energy. 44(14):7574-7582 |
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63. Mungyu Lee., C. Nagendranatha Reddy., Min B. In situ integration of microbial electrochemical systems |
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into an aerobic digestion to improve methane fermentation at different substrate concentrations. International journal of Hydrogen Energy. 44(4):2380-2389 |
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2018 |
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62. A. Naresh Kumar.,Min B., S. Venkata Mohan. Defatted algal biomass as feedstock for |
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chain carboxylic acids and biohydrogen production in the biorefinery format. Bioresource Technology. 269:408-416. |
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61. Kondaveeti S., Kakarla R., Kim H., Kim B., Min B. The performance and long-term stability of low-cost |
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separators in single chamber bottle type microbial fuel cells. Environmental Techonology. 38:1-10. |
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2017 |
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60. Hai T.H., Kakarla R., Min B. Algae cathode microbial fuel cells for electricity generation and nutrient |
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removal from landfill leachate wastewater. International Journal of Hydrogen Energy. 42:29433-29442. |
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59. Kondaveeti S., Moon J., Min B. Optimum spacing between electrodes in an air-cathode single chamber |
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microbial fuel cell with a low-cost polypropylene separator. Bioprocess and Biosystems Engineering. 40(12):1851-1858. |
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58. Choi K., Kondaveeti S., Min B. Bioelectrochemical methane (CH4) production in anaerobic digestion at |
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different supplemental voltages. Bioresource Technology. 245(A):826-832. |
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57. El-Sayed Salama., Mayur B. Kurade., Reda A. I., Abou-Shanab., Marwa M., El-Dalatony., |
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Il-seung Yang., Min B., Byong-Hun Jeon. Recent progress in microalgal biomass production coupled with wastewater treatment for biofule generation. Renewable and Sustainable Energy Reviews.79:1189-1211. |
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56. Luguang Wang., Beizhen Xie., Ningshengjie Gao., Min B., Hong Liu. Urea removal coupled with |
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enhanced electricity generation in single-chambered microbial fuel cells. Environmental Science and Pollution Research. 24(25):20401-20408. |
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55. Park Y., Cho H., Yu J., Min B., Kim H., Kim B., Lee T. Response of microbial community structure to |
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pre-acclimation strategies in microbial fuel cells for domestic wastewater treatment. Bioresource Techonology. 233:176-183 |
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54. Sigdel, A., Jung, W., Min, B., Lee, M., Choi, U., Timmes, T., Kimb, S.J., Kang, C.U., Kumar, R., Jeon, |
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B.H. Concurrent removal of cadmium and benzene from aqueous solution by powdered activated carbon impregnated alginate beads. CATENA. 148(1):101-107. |
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2016 |
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53. Na. Li., Kakarla, R., Min, B. Effect of influential factors on microbial growth and the correlation between |
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current generation and biomass in an air cathode microbial fuel cell. International Journal of Hydrogen Energy. 41(45):20606-20614. |
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2015 |
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52. Kondaveeti S., Min B. Bioelectrochemical reduction of volatile fatty acids in anaerobig digestion effluent |
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for the production of biofuels. Water Research. 87:137-144. |
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51. Na .L., Kakarla. R., Moon. J.M., Min B. Determination of Microbial Growth by Protein Assay in an Air- |
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Cathode Single Chamber Microbial Fuel Cell. Journal of Microbiology and Biotechnology. 25 (7):1114-1118. |
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50. Kakarla R., Kim J.R., Jeon B.H., Min B. Enhanced performance of an air–cathode microbial fuel cell |
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with oxygen supply from an externally connected algal bioreactor. Bioresource Technology. 195:210-216. |
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49. Moon. J.M., Kondaveeti S., Lee T.H., Song Y.C., Min. B. Minimum interspatial electrode spacing for |
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optimizing air-cathode microbial fuel cell (MFC) operation with membrane electrode. Bioelectrochemistry.106(B):263-267. |
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48. Moon J.M., Kondaveeti S., Min B. Evaluation of low-cost separators for increased power generation |
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in single chamber microbial fuel cells with membrane electrode assembly. Fuel Cells. 15(1):230-238. |
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47. Lee S.H., Hwang J.H., Kabra A.N., Abou-Shanab R.A., Kurade M.B., Min B., Jeon B.H. Perchlorate |
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reduction from a highly concentrated aqueous solution by bacterium Rhodococcus sp. YSPW03. Encironmental Science and Pollution Research. 22(23):18839-18848. |
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46. Kumar M.S., Kabra A.N., Min B., El-Dalatony M.M., Xiong J., Thajuddin N., Lee D.S., Jeon B.H. |
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Insecticides induced biochemical changes in freshwater microalga Chlamydomonas Mexicana. Encironmental Science and Pollution Research.23(2):1091-1099. |
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2014 |
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45. El-Sayed S., Akhil N. K., Ji M.K., Kim J.R., Min B., Jeon B.H. Enhancement of microalgae growth and |
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fatty acid content under the influence of phytohormones. Bioresource Technology. 172:97-103. |
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44. Kondaveeti S., Lee S.H., Park H.D., Min B. Bacterial communities in a bioelectrochemical denitri-fication |
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system: The effects of supplemental electron acceptors. Water Research 51:25-36. |
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43. Kondaveeti S., Lee J., Kakarla R., Kim H.S., Min B. Low-cost separators for enhanced power productin |
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and field application of microbial fuel cells (MFCs). Electrochimica Acta. 132:434-440. |
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42. Kakarla R., Min B. Photoautotrophic microalgae Scenedesmus obliquus attached on a cathode as oxygen |
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producers for microbial fuel cell (MFC) operation. International Journal of Hydrogen Energy. 39:10275-10283. |
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41. Kakarla R., Min B. Evaluation of microbial fuel cell operation using algae as an oxygen supplier: |
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carbon paper cathode vs. carbon brush cathode. Bioprocess and Biosystem Engineering. 37(12):2453-61. |
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40. Kondaveeti S., Choi K.S., Min B. Microalgae Scenedesmus obliquus as renewable biomass feedstock for |
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electricity generation in microbial fuel cells (MFCs). Frontiers of Environmental Science and Engineering. 8(5):784-791. |
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39. Hur J., Lee B.M., Choi K.S., Min B. Tracking the spectroscopic and chromatographic changes of algae |
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derived organic matter in a microbial fuel cell. Environmental Science and Pollution Research21(3):2230-9. |
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2013 |
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38. Lee S.H., Kondaveeti S., Min B., Park H.D. Enrichment of Clostridia during the operation of an external |
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powered bio-electrochemical denitrification system.Process Biochemistry. 48:306-311. |
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37. Kondaveeti S., Min B. Nitrate reduction with biotic and abiotic cathodes at various cell voltages in |
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bioelectrochemical denitrification system. Bioprocess Biosyst. Eng. 36:231-238. |
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36. Vologni V., Kakarla R., Angelidaki I., Min B. Increased power generation from primary sludge by a |
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submersible microbial fuel cell and optimum operation conditions. Bioprocess Biosyst. Eng. 36(5):635-642. |
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2012 |
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35. Min B., Poulsen F.W., Thygesen A., Angelidaki I. Electric power generation by a submersible |
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microbial fuel cell equipped with a membrane electrode assembly. Bioresource Technology 118: 412-417. |
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34. Lee M.J., Kim T.H., Min B., Hwang S.J. Sodium concentration effects on metabolic pathway |
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and estimation of ATP use in dark fermentation hydrogen production through stoichiometric analysis. Journal of Environmental Management 108: 22-26. |
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33. Lim J.J., Kim M.H., Kim M.J., Oh T.S., Kang O.Y., Min B., Rao A.S., You C.K. A systematic |
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model calibration methodology based on multiple errors minimization method for the optimal parameter estimation of ASM1. Korean J. Chem. Eng. 29(3):291-303. |
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2011 |
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32. Thygesen A., Poulsen F.W., Angelidaki I., Min B., Bjerre A.B. Electricity generation by microbial |
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fuel cells fueled with wheat straw hydrolysate. Biomass and Bioenergy 35: 4732-4739. |
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31. Fang C., Min B., Angelidaki I. Nitrate as an Oxidant in the Cathode Chamber of a Microbial Fuel |
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Cell for Both Power Generation and Nutrient Removal Purposes. Appl. Biochem. Biotechnol 164: 464-474. |
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30. Peixoto L., Min B., Martins G., Brito A.G., Kroff P., Parpot P., Angelidaki I., Nogueira R. In situ |
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microbial fuel cell-based biosensor for organic carbon. Bioelectro chemistry 81: 99-103. |
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29. Zhang Y., Min B., Huang L., Angelidaki I. Electricity generation and microbial community |
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response to substrate changes in microbial fuel cell. Bioresources Technology 102(2): 1163-1173. |
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28. Hwang J.H., Choi J.A., Abou-Shanab R.A.I., Min B., Song H., Kim Y., Lee E.S., Jeon B.H. |
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Feasibility of hydrogen production from ripened fruits by a combined two-stage (dark/dark) fermentation system. Bioresources Technology 102(2): 1051-1058. |
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27. Kim T.H., Lee M.J., JangH.S., Min B.K., Yoo G.Y., Hwang S.J. Characteristics of N2O |
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release from fluidized media type BNR processes and identifi cation of N2O sources. Desalination and Water Treatment 28: 378-384. |
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26. Choi J-A., Hwang J.H., Dempsey B.A., Abou-Shanab R.A.I., Min B., Song H., Lee D.S., Kim J.R., |
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Cho Y.C., Hong S., Jeon B.H. Enhancement of fermentative bioenergy (ethanol/hydrogen) production using ultrasonication of Scenedesmus obliquus YSW15 cultivated in swine wastewater effluent. Energy and Environmental Science 4: 3513-3520. |
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25. Abou-Shanab R.A.I., Hwang J.H., Cho Y., Min B., Jeon B.H. Characterization of microalgal species |
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isolated from fresh water bodies as a potential source for biodiesel production. Applied Energy 88(10): 3300-3306. |
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24. Hwang J.H., Choi J.A., O Y.K., Abou-Shanab R.A.I., Song H., Min B., Cho Y., Na J.G., Koo J., |
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Jeon B.H. Hydrogen production from sulfate-and ferrous-enriched wastewater. International Journal of Hydrogen Energy 36: 13984-13990 |
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23. Khan M.A., Ahn Y.T., Kumar M., Lee W., Min B., Kim G., Cho D.W., Park W.B., Jeon B.H. |
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Adsorption studies for the removal of nitrate using modified lignite granular activated carbon. Separation Science and Technology 46(16):2575-2584 |
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2010 |
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22. Kongjan P., O-Thong S., Kotay M., Min B., Angelidaki I. Biohydrogen production from wheat straw |
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hydrolysate by dark fermentation using extreme thermophilic mixed culture. Biotechnology and Bioengineering 105 (5):899-908. |
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21. Kumar E., Bhatnagar A., Choi J.A., Kumar Umesh, Min B., Kim Y., Song H., Paeng K.J., |
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Jung Y.M., Abou-Shanab R.A.I., Jeon B.H. Perchlorate Removal from aqueous solutions by granular ferric hydroxide (GFH). Chemical Engineering Journal 159: 84-90. |
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20. Lee M.J., Kim T.H., You G.Y., Min B., Hwang S.J. Reduction of sewage sludge by ball mill |
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pretreatment and Mn catalytic ozonation. KSCE Journal of Civil Engineering 14(5):693-697. |
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2009 |
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19. Zhang Y., Min B., Huang L., Angelidaki I. Generation of electricity and analysis of microbial |
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communities of wheat straw biomass- powered microbial fuel cells. Applied and Environmental Microbiology 75(11):3389-3395. |
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18. Thygesen A., Poulsen F.W., Min B., Angelidaki I., Thomsen A.B. The effect of different substrates |
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and humic acids on power generation in microbial fuel cell (MFC) operation. Bioresource Technology 103(3):1186-1191. |
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17. Hwang J.H., Choi J.A., Abou-Shanab R.A.I., Bhatnagar A., Min B., Song H., Kumar E., Choi J., |
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Lee E. S., Kim Y. J., Um S., Lee D. S., Jeon B.H. Effect of pH and Sulfate concentration on hydrogen production using anaerobic mixed microflora. International Journal of Hydrogen Energy 34(24):9702-9710. |
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16. Hwang J.H., Cha G.C., Jeong T.Y., Kim D.J., Bhatnagar A., Min B., Song H., Choi J.A., Lee J.H., |
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Jeong D.W., Chung H.K., Choi J., Jeon B.H. Effect of chemical oxygen demand/sulfate ratio and hydraulic retention time (HRT) variation on fermentative hydrogen production. Water Research. 43(14):3525-33. |
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15. Kongjan P., Min B., Angelidaki I. Bio-hydrogen production from Xylose under |
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hyperthermophilic temperature (70ºC) using mixed cultures. Water Research. 43(5):1414-1424. |
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2008 |
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14. Liu D., Min B., Angelidaki I. Biohydrogen production from household solid waste (HSW) at |
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hyperthermiphilic temperature (70ºC) – Influence of pH and acetate concentration. International Journal of Hydrogen Energy. 33(23):6985-6992. |
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13. Bhatnagar A., Minocha A. K., Pudasainee D., Chung H.K., Kim S.H., Kim H.S., Lee G., Min B., |
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Jeon B-H. Vanadium removal from water by waste metal sludge and cement immobilization. Chemical Engineering Journal 144(2):197-204. |
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12. Min B., Roman O.B., Angelidaki I. Importance of temperature and anodic medium |
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composition on microbial fuel cells (MFC) performance. Biotechnology Letters. 30:1213-1218. |
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11. Bhatnagar A., Ji M., Choi Y.H., Jung W., Lee S.H., Kim S.J., Lee G., Suk H., Min B., Kim S.H., |
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Jeon B.H., Kang J.W. Removal of nitrate from water by adsorption onto zinc chloride treated activated carbon. Separation Science and Technology. 43 (4):886-907. |
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10. Min B., Angelidaki I. Innovative microbial fuel cell for electricity production from anaerobic |
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reactors. Journal of Power Sources. 180(1):641-647. |
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2007 |
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9. Ji M., Choi Y.H., Jung W., Lee S.H., Kim S.J., Min B., Bhatnagar A., Kim S.H., Chung H.K., |
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Jeon B-H., Kang J.W. Adsorption of Nitrate-N onto ZnCl2 – treated Granular Activated Carbon. Geosystem Engineering. 44(6): 492-499. |
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2005 |
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8. Min B., Kim J., Oh S.E., Regan J.M., Logan B.E. Electricity generation from swine wastewater |
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using microbial fuel cells. Water Research 39(20):4961-4968. |
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7. Min B., Cheng S., Logan B.E. Electricity generation using salt bridge and membrane |
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microbial fuel cells. Water Research 39(5):942-952. |
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6. Kim J., Min B., Logan B.E. Evaluation of procedures to acclimate a microbial fuel cell (MFC) |
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for electricity production. Applied Microbiology and Biotechnology. 68(1):23-30. |
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2004 |
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5. Min B., Logan B.E. Continuous electricity generation from domestic wastewater and |
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pure organic substrates in a flat plate microbial fuel cell (FPMFC). Environ. Sci. Technol. 38(21), 5809 – 5814. |
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4. Oh S.E., Min B., Logan B.E. Cathode performance as a factor in electricity generation in |
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microbial fuel cells. Environ. Sci. Technol. 38(18), 4900 – 4904. |
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3. Min B., Evans P.J., Chu A., Logan B.E. Perchlorate removal in sand and plastic media |
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bioreactors. Water Research, 38(1):47-60. |
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2. Min B., Kohler D., Logan B.E. A simplified HBOD test protocol based on oxygen measurements |
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using a fiber optic (HBOD) probe. Water Environ. Res., 76(1):39-47. |
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2003 |
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1. Xu J., Song Y., Min B., Steinberg L., Logan B.E. Microbial degradation of perchlorate: |
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principles and applications. Environ. Engin. Sci., 20(5): 405-422. |
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