연구동향 분석

Algae-cathode microbial fuel cell for electricity generation along with nutrient removal in batch and continuous mode operations

NGUYEN THI HOANG HAI 2020년

논문상세정보
인용/피인용
' Algae-cathode microbial fuel cell for electricity generation along with nutrient removal in batch and continuous mode operations' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • Algae
  • Microbial fuel cell
  • batch mode
  • continuous mode
  • electricity generation
  • nutrient removal
  • wastewater treatment
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
158 0

0.0%

' Algae-cathode microbial fuel cell for electricity generation along with nutrient removal in batch and continuous mode operations' 의 참고문헌

  • van Niftrik, L., Jetten, M.S.M., 2012. Anaerobic Ammonium-Oxidizing Bacteria: Unique Microorganisms with Exceptional Properties. Microbiol. Mol. Biol. Rev. 76, 585–596. https://doi.org/10.1128/MMBR.05025-11
  • http://www.fao.org/3/w3732e/w3732e06.htm, 1996.
    [1996]
  • http://www.fao.org/3/w3732e/w3732e06.htm (accessed on January 29th, 2020).
    [2020]
  • [5] Abdel-Raouf N, Al-Homaidan AA, Ibraheem IBM. Microalgae and wastewater treatment. Saudi Journal of Biological Sciences. 2012;19:257-75.
    19:257-75 [2012]
  • [27] Turpin DH. EFFECTS OF INORGANIC N AVAILABILITY ON ALGAL PHOTOSYNTHESIS AND CARBON METABOLISM. Journal of phycology. 1991;27:14-20.
  • [22] Uehlinger U. Bacteria and phosphorus regeneration in lakes. An experimental study. Hydrobiologia. 1986;135:197-206.
  • [1] Kakarla R, Min B. Photoautotrophic microalgae Scenedesmus obliquus attached on a cathode as oxygen producers for microbial fuel cell (MFC) operation. International Journal of Hydrogen Energy. 2014;39:10275-83.
  • [17] Przytocka-Jusiak M, Młynarczyk A, Kulesza M, Mycielski R. Properties of Chlorella vulgaris strain adapted to high concentration of ammonium nitrogen. Acta Microbiol Pol. 1977;26:185-97.
  • [11] You SJ, Zhao QL, Jiang JQ, Zhang JN, Zhao SQ. Sustainable approach for leachate treatment: electricity generation in microbial fuel cell. Journal of Environmental Science and Health Part A. 2006;41:2721-34.
  • Zhang, Y., Zhao, Y., Zhou, M., 2019. A photosynthetic algal microbial fuel cell for treating swine wastewater. Environ. Sci. Pollut. Res. 26, 6182–6190. https://doi.org/10.1007/s11356-018-3960-4
  • Zero-waste algal biorefinery for bioenergy and biochar : A green leap towards achieving energy and environmental sustainability
    650 , 2467-2482 [2019]
  • Wu, X.Y., Song, T.S., Zhu, X.J., Wei, P., Zhou, C.C., 2013. Construction and operation of microbial fuel cell with Chlorella vulgaris biocathode for electricity generation. Appl. Biochem. Biotechnol. 171, 2082–2092. https://doi.org/10.1007/s12010-013-0476-8
  • Wastewater treatment and microbial communities in an integrated photo-bioelectrochemical system affected by different wastewater algal inocula
    12 , 446–454 . https : //doi.org/10.1016/j.algal.2015.10.008 [2015]
  • Waste Biorefinery : A New Paradigm for a Sustainable Bioelectro Economy
    34 , 852-855 . [2016]
  • Wang, Z., Zheng, Y., Xiao, Y., Wu, S., Wu, Y., Yang, Z., Zhao, F., 2013. Analysis of oxygen reduction and microbial community of air-diffusion biocathode in microbial fuel cells. Bioresour. Technol. 144, 74–79. https://doi.org/10.1016/j.biortech.2013.06.093114
  • Wang, Y., Lin, Z., Su, X., Zhao, P., Zhou, J., He, Q., Ai, H., 2019. Cost-effective domestic wastewater treatment and bioenergy recovery in an immobilized microalgal-based photoautotrophic microbial fuel cell (PMFC). Chem. Eng. J. 372, 956–965. https://doi.org/https://doi.org/10.1016/j.cej.2019.05.004
  • Vetiver and Dictyosphaerium sp . co-culture for the removal of nutrients and ecological inactivation of pathogens in swine wastewater .
    20 , 71–78 . https : //doi.org/10.1016/j.jare.2019.05.004 [2019]
  • Velpuri J. Algae—The Potential Future Fuel : Challenges and Prospects
  • V2O5 microflower decorated cathode for enhancing power generation in air-cathode microbial fuel cell treating fish market wastewater
    41 , 3638-3645
  • Utilisation of waste medicine wrappers as an efficient low-cost electrode material for microbial fuel cell
    0 , 1-10
  • Using live algae at the anode of a microbial fuel cell to generate electricity
    22 , 15621-15635 [2015]
  • Using a tubular photosynthetic microbial fuel cell to treat anaerobically digested effluent from kitchen waste : Mechanisms of organics and ammonium removal
    https : //doi.org/10.1016/j.biortech.2018.01.144 [2018]
  • Use of ammoniacal nitrogen tolerant microalgae in landfill leachate treatment
    27:1376-82 [2007]
  • Use of Microalgae for Advanced Wastewater Treatment and Sustainable Bioenergy Generation
    0 , 1-17 [2016]
  • Treatment of landfill leachates with biological pretreatments and reverse osmosis
    17 , 1177–1193 . https : //doi.org/10.1007/s10311-019-00860-6113 [2019]
  • Treatment of landfill leachate using microbial fuel cells : Alternative anodes and semi-continuous operation
    139:383-7 [2013]
  • Toxic effect of landfill leachate on microalgae . Water , Air , and Soil Pollution
    69:337-49 [1993]
  • Towards sustainable wastewater treatment by using microbial fuel cells-centered technologies
    7 , 911-924 [2014]
  • Towards an engineering-oriented strategy for building microbial anodes for microbial fuel cells
    14 , 13332-13343 [2012]
  • Torres, C.I., Marcus, A.K., Lee, H.-S., Parameswaran, P., Krajmalnik-Brown, R., Rittmann, B.E., 2010. A kinetic perspective on extracellular electron transfer by anoderespiring bacteria. FEMS Microbiol. Rev. 34, 3–17. https://doi.org/10.1111/j.1574- 6976.2009.00191.x
  • Tiwari, B., Singh, S., Chakraborty, S., Verma, E., Mishra, A.K., 2017. Sequential role of biosorption and biodegradation in rapid removal degradation and utilization of methyl parathion as a phosphate source by a new cyanobacterial isolate Scytonema sp. BHUS-5. Int. J. Phytoremediation 19, 884–893. https://doi.org/10.1080/15226514.2017.1303807
  • Thomen, P., Robert, J., Monmeyran, A., Bitbol, A.-F., Douarche, C., Henry, N., 2017. Bacterial biofilm under flow: First a physical struggle to stay, then a matter of breathing. PLoS One 12, e0175197–e0175197. https://doi.org/10.1371/journal.pone.0175197
  • The role of renewable energy in the global energy transformation .
    [2019]
  • The rise of graphene
    6 , 183-191 [2007]
  • The nutrient stoichiometry of benthic microalgal growth : Redfield proportions are optimal
    44 , 440–446 . https : //doi.org/10.4319/lo.1999.44.2.0440 [1999]
  • The effect of different light intensities and light/dark regimes on the performance of photosynthetic microalgae microbial fuel cell
    [2018]
  • The Environmental Biorefinery : Using Microalgae to Remediate Wastewater , aWin-Win Paradigm
    9 , 2-19 . [2016]
  • Temperature effects on photosynthetic capacity , respiration , and growth rates of bloom‐ forming cyanobacteria
    21 , 391-399 . [1987]
  • Temperature effects on growth and buoyancy of Microcystis aeruginosa .
    40 , 16-28 . [2018]
  • Techno-productive potential of photosynthetic microbial fuel cells through different configurations
    39 , 617-627 [2014]
  • Techno-economic assessment of the sustainability of an integrated biorefinery from microalgae and Jatropha : A review and case study
    88 , 239-257
  • Sustainable treatment of landfill leachate
    [2015]
  • Sustainable power generation from bacterio-algal microbial fuel cells ( MFCs ) : An overview
    73 , 75–84 . https : //doi.org/10.1016/j.rser.2017.01.115112 [2017]
  • Sustainable electricity generation and ammonium removal by microbial fuel cell with a microalgae assisted cathode at various environmental conditions
    284 , 161–167 . https : //doi.org/https : //doi.org/10.1016/j.biortech.2019.03.111 [2019]
  • Sustainable approach for leachate treatment : electricity generation in microbial fuel cell
    41 , 2721–2734 . [2006]
  • Study of a photosynthetic MFC for energy recovery from synthetic industrial fruit juice wastewater
    39 , 21828–21836 [2014]
  • Steck A. Cation and water diffusion in Nafion ion exchange membranes : influence of polymer structure
    128:1880-4 [1981]
  • Standard Methods for the Examination of Water and Wastewater
    [2005]
  • Standard Methods for the Examination of Water & Wastewater , Standard Methods for the Examination of Water and Wastewater
    [2005]
  • Stainless steel foam increases the current produced by microbial bioanodes in bioelectrochemical systems .
    7 , 1633-1637 . [2014]
  • SingleChamber microbial fuelCell ( SCMFC ) with aCathodic microalgal biofilm : A preliminary assessment of the generation of bioelectricity and biodegradation of real dye textile wastewater
    https : //doi.org/10.1016/j.chemosphere.2017.02.099138 [2017]
  • Simultaneous wastewater treatment , electricity generation and biomass production by an immobilized photosynthetic algal microbial fuelCell .
    37 , 873-880 . [2014]
  • Simultaneous organicCarbon , nutrients removal and energy production in a photomicrobial fuelCell ( PFC )
    4 , 4340-4346 .
  • Shukla, M., Kumar, S., 2018. Algal growth in photosynthetic algal microbial fuel cell and its subsequent utilization for biofuels. Renew. Sustain. Energy Rev. 82, 402–414. https://doi.org/10.1016/j.rser.2017.09.067
  • Sequestration ofCO2 discharged from anode by algalCathode in microbialCarbonCaptureCells ( MCCs )
    25 , 2639-2643 . [2010]
  • Separators used in microbial electrochemical technologies :Current status and future prospects
    195 , 170-179 [2015]
  • Self-sustained phototrophic microbial fuelCells based on the synergisticCooperation between photosynthetic microorganisms and heterotrophic bacteria
    43 , 1648–1654 . https : //doi.org/10.1021/es803084a [2009]
  • Self-sustainable electricity production from algae grown in a microbial fuelCell system
    82 , 87-93 [2015]
  • Selective enrichment of biocatalysts for bioelectrochemical systems : ACritical review
    109 , 10-23 [2019]
  • Saxena, R.C., Adhikari, D.K., Goyal, H.B., 2009. Biomass-based energy fuel through biochemical routes: A review. Renew. Sustain. Energy Rev. 13, 167–178. https://doi.org/10.1016/j.rser.2007.07.011
  • S. Bicarbonate produced fromCarbonCapture for algaeCulture .
    29:537-41 [2011]
  • Review of theCultivation program within the National Alliance for Advanced Biofuels and Bioproducts
    22:166-86 [2017]
  • Reduced graphene oxide and biofilms asCathodeCatalysts to enhance energy and metal recovery in microbial fuelCell
    283 , 129-137 [2019]
  • Redfield , A.C. , 1934 . On the proportions of organic derivatives in sea waterZ. ,Co , A.C. , 2017 . Sustainable power generation from bacterio-algal microbial
  • Recent advances in municipal landfill leachate : A review focusing on itsCharacteristics , treatment , and toxicity assessment
    https : //doi.org/https : //doi.org/10.1016/j.scitotenv.2019.135468 [2019]
  • Quantification of the internal resistance distribution of microbial fuelCells
    42 , 8101-8107 [2008]
  • Qiao R. Understanding Ammonium Transport in Bioelectrochemical Systems towards its Recovery
    6:22547 [2016]
  • Production of biodiesel from microalgae through biologicalCarbonCapture : a review
    7 , 1-21 . [2017]
  • Production of Electricity during Wastewater Treatment Using a SingleChamber Microbial FuelCell
    38 , 2281-2285 [2004]
  • Present and Long-TermComposition of MSW Landfill Leachate : A Review
    32 , 297–336 . https : //doi.org/10.1080/10643380290813462 [2002]
  • Power generation from wastewater using singleChamber microbial fuelCells ( MFCs ) with platinum-freeCathodes and pre-colonized anodes .
    62 , 8-16 . [2012]
  • Power generation enhancement in novel microbialCarbonCaptureCells with immobilizedChlorella vulgaris .
    214 , 216-219 . [2012]
  • Potential of porousCo3O4 nanorods asCathodeCatalyst for oxygen reduction reaction in microbial fuelCells .
    220 , 537-542 . [2016]
  • Potential of mixed microalgae to harness biodiesel from ecological water-bodies with simultaneous treatment .
    102 , 1109-1117 . [2011]
  • Potential applications of algae in theCathode of microbial fuelCells for enhanced electricity generation with simultaneous nutrient removal and algae biorefinery :Current status and future perspectives
    https : //doi.org/10.1016/j.biortech.2019.122010 [2019]
  • Potential application of microalgae in produced water treatment . Desalin . Water Treat
    135 , 47–58 . https : //doi.org/10.5004/dwt.2018.23146 [2018]
  • Photosynthetic microbial fuelCell with polybenzimidazole membrane : synergy between bacteria and algae for wastewater removal and biorefinery
    4 , 1-26 [2018]
  • Photosynthetic membrane-less microbial fuelCells to enhance microalgal biomassConcentration
    218 , 1016-1020 [2016]
  • Photoelectrode , photovoltaic and photosynthetic microbial fuelCells
    90 , 16-27 [2018]
  • Photoautotrophic microalgae Scenedesmus obliquus attached on aCathode as oxygen producers for microbial fuelCell ( MFC ) operation
    https : //doi.org/10.1016/j.ijhydene.2014.04.158
  • Performance of microbial fuel cell subjected to variation in pH , temperature , external load and substrate concentration
    100 , 717-723 [2009]
  • Pareau D. Nitrogen and phosphate removal from wastewater with a mixed microalgae and bacteria culture
    11:18-26 [2016]
  • Oxygen diffusion in cation-form Nafion membrane of microbial fuel cells
    276 , 268–283 . https : //doi.org/10.1016/j.electacta.2018.04.158 [2018]
  • Overview of the potential of microalgae for CO2 sequestration .
    11 , 2103-2118 [2014]
  • Optimization of hydraulic retention time and biomass concentration in microalgae biomass production from treated sewage with a membrane photobioreactor
    15 , 1–11 . https : //doi.org/10.2965/jwet.15-085 [2017]
  • Optimization of growth conditions of different algal strains and determination of their lipid contents
    [2015]
  • On the Proportions of Organic Derivatives in Sea Water and Their Relation to the Composition of Plankton
    1934:176 - 92
  • Nutrient removal and electricity production from wastewater using microbial fuel cell technique
    365 , 92–98 . https : //doi.org/https : //doi.org/10.1016/j.desal.2015.02.021 [2015]
  • Novel mesoporous MnCo2O4 nanorods as oxygen reduction catalyst at neutral pH in microbial fuel cells
    254 , 1-6 [2018]
  • Novel Analytical Microbial Fuel Cell Design for Rapid in Situ Optimisation of Dilution Rate and Substrate Supply Rate
    by Flow , Volume Control and Anode Placementhttps : //doi.org/10.3390/en11092377 [2018]
  • Nitrification , denitrification , and dephosphatation capability of activated sludge during co-treatment of intermediate-age landfill leachates with municipal wastewater .
    [2018]
  • Nitrate as an Oxidant in the Cathode Chamber of a Microbial Fuel Cell for Both Power Generation and Nutrient Removal Purposes
    164 , 464-474 [2011]
  • Nguyen, H.T.H., Kakarla, R., Min, B., 2017. Algae cathode microbial fuel cells for electricity generation and nutrient removal from landfill leachate wastewater. Int. J. Hydrogen Energy 42, 29433–29442. https://doi.org/https://doi.org/10.1016/j.ijhydene.2017.10.011
  • Moulin P. Landfill leachate treatment : Review and opportunity .
    150:468-93 [2008]
  • Modified conductive polyaniline-carbon nanotube composite electrodes for bioelectricity generation and waste remediation
    284 , 148-154 [2019]
  • Microbial fuel cells to recover heavy metals
    12 , 483-494 [2014]
  • Microbial fuel cells for wastewater treatment
    54 , 9-15 [2006]
  • Microbial fuel cells : Methodology and technology
    40 , 5181–5192 . https : //doi.org/10.1021/es0605016 [2006]
  • Microbial fuel cells : An overview of current technology
    101 , 60-81 [2019]
  • Microbial fuel cell with an algae-assisted cathode : A preliminary assessment
    242 , 638-645 [2013]
  • Microbial fuel cell powered by lipid extracted algae : A promising system for algal lipids and power generation
    https : //doi.org/10.1016/j.biortech.2017.09.119 [2018]
  • Microbial fuel cell application in landfill leachate treatment
    [2011]
  • Microbial community dynamics in two-chambered microbial fuel cells : Effect of different ion exchange membranes
    90 , 1497-1506 [2015]
  • Microbial community analysis in biocathode microbial fuel cells packed with different materials
    2 , 1–8 . https : //doi.org/10.1186/2191-0855-2-21 [2012]
  • Microbial carbon capture cell using cyanobacteria for simultaneous power generation , carbon dioxide sequestration and wastewater treatment
    107 , 97-102 [2012]
  • Microalgal Heterotrophic and Mixotrophic Culturing for Bio-refining : From Metabolic Routes to Techno-economics . In : Prokop A. , Bajpai R. , Zappi M. ( eds ) Algal Biorefineries
    [2015]
  • Microalgae- A promising tool for heavy metal remediation
    113 , 329-352 [2015]
  • Microalgae as substrate in low cost terracotta-based microbial fuel cells : Novel application of the catholyte produced .
    209 , 380–385 . https : //doi.org/https : //doi.org/10.1016/j.biortech.2016.02.083 [2016]
  • Microalgae and wastewater treatment
    19 , 257-275 [2012]
  • Micro-algae cultivation for biofuels : Cost , energy balance , environmental impacts and future prospects
    [2013]
  • Marine microbial fuel cell : Use of stainless steel electrodes as anode and cathode materials
    53 , 468-473 [2007]
  • Marine algal carbohydrates as carbon sources for the production of biochemicals and biomaterials
    36 , 798-817 [2018]
  • Mansfeld F. Effect of electrolyte pH on the rate of the anodic and cathodic reactions in an air-cathode microbial fuel cell
    74:78-82 [2008]
  • Manganese dioxide as an alternative cathodic catalyst to platinum in microbial fuel cells
    24 , 2825 , 2829 [2009]
  • Ma, J., Wang, Z., Zhang, J., Waite, T.D., Wu, Z., 2017. Cost-effective Chlorella biomass production from dilute wastewater using a novel photosynthetic microbial fuel cell (PMFC). Water Res. 108, 356–364. https://doi.org/10.1016/j.watres.2016.11.016
  • Ma, J., Wang, Z., Zhang, J., Waite, T.D., Wu, Z., 2017. Cost-effective Chlorella biomass production from dilute wastewater using a novel photosynthetic microbial fuel cell ( PMFC ). Water Res. 108, 356–364. https://doi.org/10.1016/j.watres.2016.11.016111
  • Light intensity affects the performance of photo microbial fuel cells with Desmodesmus sp . A8 as cathodic microorganism
    116 , 86-90 [2014]
  • Li, M., Zhou, M., Luo, J., Tan, C., Tian, X., Su, P., Gu, T., 2019. Carbon dioxide sequestration accompanied by bioenergy generation using a bubbling-type photosynthetic algae microbial fuel cell. Bioresour. Technol. 280, 95–103. https://doi.org/https://doi.org/10.1016/j.biortech.2019.02.038
  • Lee K. Ammonia removal from anaerobic digestion effluent of livestock waste using green alga Scenedesmus sp .
    101:8649-57 [2010]
  • Leachate treatment and electricity generation using an algae-cathode microbial fuel cell with continuous flow through the chambers in series
    https : //doi.org/https : //doi.org/10.1016/j.scitotenv.2020.138054 [2020]
  • Landfill leachate treatment with microbial fuel cells ; scale-up through plurality
    100:5085-91 [2009]
  • Landfill leachate treatment : Review and opportunity .
    150 , 468–493 . https : //doi.org/10.1016/j.jhazmat.2007.09.077 [2008]
  • Landfill leachate : A promising substrate for microbial fuel cells
    [2017]
  • Kuntke, P., Śmiech, K.M., Bruning, H., Zeeman, G., Saakes, M., Sleutels, T.H.J.A., Hamelers, H.V.M., Buisman, C.J.N., 2012. Ammonium recovery and energy production from urine by a microbial fuel cell. Water Res. 46, 2627–2636. https://doi.org/10.1016/j.watres.2012.02.025
  • Kim, J.R., Zuo, Y., Regan, J.M., Logan, B.E., 2008. Analysis of ammonia loss mechanisms in microbial fuel cells treating animal wastewater. Biotechnol. Bioeng. 99, 1120–1127. Kuntke, P., Śmiech, K.M., Bruning, H., Zeeman, G., Saakes, M., Sleutels, T.H.J.A., Hamelers, H.V.M., Buisman, C.J.N., 2012. Ammonium recovery and energy production from urine by a microbial fuel cell. Water Res. 46, 2627–2636. https://doi.org/10.1016/j.watres.2012.02.025
  • Kakarla, R., Min, B., 2014a. Evaluation of microbial fuel cell operation using algae as an oxygen supplier: carbon paper cathode vs. carbon brush cathode. Bioprocess Biosyst. Eng. https://doi.org/10.1007/s00449-014-1223-4110
  • Kakarla, R., Min, B., 2014a. Evaluation of microbial fuel cell operation using algae as an oxygen supplier: carbon paper cathode vs. carbon brush cathode. Bioprocess Biosyst. Eng. https://doi.org/10.1007/s00449-014-1223-4
  • Jung, R.K., Zuo, Y., Regan, J.M., Logan, B.E., 2008. Analysis of ammonia loss mechanisms in microbial fuel cells treating animal wastewater. Biotechnol. Bioeng. 99, 1120–1127. https://doi.org/10.1002/bit.21687
  • Isolation of a novel microalgae strain Desmodesmus sp . and optimization of environmental factors for its biomass production
    148 , 249-254 [2013]
  • Ion exchange membranes as separators in microbial fuel cells for bioenergy conversion : A comprehensive review
    28 , 575-587 [2013]
  • Investigation of optimal condition for Chlorella vulgaris microalgae growth
    3 , 217-230 [2017]
  • Integrated photo-bioelectrochemical system for contaminants removal and bioenergy production
    46 , 11459-11466 [2012]
  • Integrated bio-electrogenic process for bioelectricity production and cathodic nutrient recovery from azo dye wastewater
    98 , 188-196 [2016]
  • Influence of substrate concentration and feed frequency on ammonia inhibition in microbial fuel cells
    271 , 360-365 [2014]
  • Influence of microalgal N and P composition on wastewater nutrient remediation
    [2016]
  • Industrial Wastewater Treatment Using Phycoremediation Technologies and Co-Production of Value-Added Products
    9 , 1-10 . [2018]
  • Improved performance of microbial fuel cell by using conductive ink printed cathode containing Co3O4 or Fe3O4 .
    310 , 173-183 . [2019]
  • Importance of OH− Transport from Cathodes in Microbial Fuel Cells
    5:1071-9 [2012]
  • Ieropoulos I. Microbial fuel cell – A novel self-powered wastewater electrolyser for electrocoagulation of heavy metals .
    42:1813-9 [2017]
  • Hu, X., Liu, B., Zhou, J., Jin, R., Qiao, S., Liu, G., 2015. CO2 Fixation, Lipid Production, and Power Generation by a Novel Air-Lift-Type Microbial Carbon Capture Cell System. Environ. Sci. Technol. 49, 10710–10717. https://doi.org/10.1021/acs.est.5b02211
  • Hou, Q., Pei, H., Hu, W., Jiang, L., Yu, Z., 2016. Mutual facilitations of food waste treatment, microbial fuel cell bioelectricity generation and Chlorella vulgaris lipid production. Bioresour Technol. 2013, 50-55. http://www.fao.org/3/w3732e/w3732e06.htm (accessed on August 8th, 2019)
  • Hou, Q., Cheng, J., Nie, C., Pei, H., Jiang, L., Zhang, L., Yang, Z., 2017. Features of Golenkinia sp. and microbial fuel cells used for the treatment of anaerobically digested effluent from kitchen waste at different dilutions. Bioresour. Technol. 240, 130–136. https://doi.org/10.1016/j.biortech.2017.02.092
  • Hou, Q., Cheng, J., Nie, C., Pei, H., Jiang, L., Zhang, L., Yang, Z., 2017. Features of Golenkinia sp. and microbial fuel cells used for the treatment of anaerobically digested effluent from kitchen waste at different dilutions. Bioresour technol. 240, 130-136.
  • High-Performance Carbon Anode Derived from Sugarcane for Packed Microbial Fuel Cells
    4 , 168-174 . [2017]
  • Heavy metal bioaccumulation and toxicity with special reference to microalgae
    7 , 60-64 [2007]
  • Han, S.I., Lee, H.J., Whang, K.S., 2014. Chitinophaga polysaccharea sp. nov., an exopolysaccharide-producing bacterium isolated from the rhizoplane of Dioscorea japonica. Int. J. Syst. Evol. Microbiol. 64, 55–59. https://doi.org/10.1099/ijs.0.055228-0109
  • Growth kinetics of Chlorella vulgaris and its use as a cathodic half-cell
    100 , 269-274 . [2009]
  • Growth and nutrient removal in free and immobilized green algae in batch and semi-continuous cultures treating real wastewater .
    101 , 58-64 . [2010]
  • Gressler, P., Bjerk, T., Schneider, R., Souza, M., Lobo, E., Zappe, A., Corbellini, V., Moraes, M., 2014. Cultivation of Desmodesmus subspicatus in a tubular photobioreactor for bioremediation and microalgae oil production. Environ. Technol. 35, 209–219. https://doi.org/10.1080/09593330.2013.822523
  • Graphene-modified electrodes for enhancing the performance of microbial fuel cells
    7 , 7022-7029 [2015]
  • Graphene-based polyaniline nanocomposites : Preparation , properties and applications
    2 , 4491-4509 [2014]
  • Grand Challenges in Advanced Fossil Fuel Technologies
    2 , 1-3 [2014]
  • Gonzalez Del Campo, A., Perez, J.F., Cañizares, P., Rodrigo, M.A., Fernandez, F.J., Lobato, J., 2015. Characterization of light/dark cycle and long-term performance test in a photosynthetic microbial fuel cell. Fuel 140, 209–216. https://doi.org/10.1016/j.fuel.2014.09.087
  • Fuerst, J.A., Sagulenko, E., 2011. Beyond the bacterium: Planctomycetes challenge our concepts of microbial structure and function. Nat. Rev. Microbiol. 9, 403–413. https://doi.org/10.1038/nrmicro2578
  • Factors Influencing Luxury Uptake of Phosphorus by Microalgae in Waste Stabilization Ponds
    42 , 5958-5962 . [2008]
  • Evaluation of microbial fuel cell operation using algae as an oxygen supplier : carbon paper cathode vs. carbon brush cathode .
    https : //doi.org/10.1007/s00449-014-1223-4
  • Evaluation of microbial fuel cell operation using algae as an oxygen supplier : carbon paper cathode vs. carbon brush cathode .
    37:2453-61 [2014]
  • Eutrophication trends in the United States-a Problem . J. Wat
    [1966]
  • Enhancing performance of microbial fuel cell by using graphene supported V2O5-nanorod catalytic cathode .
    228 , 513-521 [2017]
  • Enhancement of power production with tartaric acid doped polyaniline nanowire network modified anode in microbial fuel cells
    192 , 831-834 [2015]
  • Enhancement of bioelectricity generation and algal productivity in microbial carbon-capture cell using low cost coconut shell as membrane separator .
    133 , 205-213 [2018]
  • Enhanced performance of an air-cathode microbial fuel cell with oxygen supply from an externally connected algal bioreactor
    [2015]
  • Enhanced electron transfer mediator based on biochar from microalgal sludge for application to bioelectrochemical systems
    [2018]
  • Enhanced electricity generation performance and dye wastewater degradation of microbial fuel cell by using a petaline NiO2 polyaniline-carbon felt anode
    [2018]
  • Enhanced denitrification and power generation of municipal wastewater treatment plants ( WWTPs ) effluents with biomass in microbial fuel cell coupled with constructed wetland
    709 , 136159. https : //doi.org/https : //doi.org/10.1016/j.scitotenv.2019.136159 [2020]
  • Enhanced Power Generation in Microbial Fuel Cell Using MnO2-Catalyzed Cathode Treating Fish Market Wastewater .
  • Engineering electrodes for microbial electrocatalysis .
    33 , 149-156 . [2015]
  • Electrode materials for microbial fuel cells : Nanomaterial approach
    4 , 1-11 [2015]
  • Electrochemical investigation of a microbial solar cell reveals a nonphotosynthetic biocathode catalyst
    79 , 3933–3942 . https : //doi.org/10.1128/AEM.00431-13 [2013]
  • Electrocatalytic Oxygen Reduction Reaction BT PEM Fuel Cell Electrocatalysts and Catalyst Layers : Fundamentals and Applications
    [2008]
  • Electricity production from macroalgae by a microbial fuel cell using nickel nanoparticles as cathode catalysts
    42 , 29874-29880 . [2017]
  • Electricity production by Geobacter sulfurreducens attached to electrodes
    69 , 1548–1555 . https : //doi.org/10.1128/AEM.69.3.1548-1555.2003 [2003]
  • Electricity generation using membrane and salt bridge microbial fuel cells
    https : //doi.org/10.1016/j.watres.2005.02.002
  • Electricity generation using membrane and salt bridge microbial fuel cells
    39 , 1675-1686 [2005]
  • Electricity generation through a photo sediment microbial fuel cell using algae at the cathode
    76 , 3269-3277 [2017]
  • Electricity generation from swine wastewater using microbial fuel cells
  • Electricity generation by microbial fuel cell using microorganisms as catalyst in cathode
    23 , 1765-1773 . [2013]
  • Electricity generation and microbial community response to substrate changes in microbial fuel cell
    102 , 1166-1173
  • Electricity generation and microalgae cultivation in microbial fuel cell using microalgae-enriched anode and biocathode
    79 , 674–680 . https : //doi.org/https : //doi.org/10.1016/j.enconman.2013.12.032108 [2014]
  • Electricity generation , desalination and microalgae cultivation in a biocathode-microbial desalination cell
    5 , 843-848 [2017]
  • Electricity and biomass production in a bacteria-Chlorella based microbial fuel cell treating wastewater
    https : //doi.org/10.1016/j.jpowsour.2017.03.097 [2017]
  • Effects of temperature and ferrous sulfate concentrations on the performance of microbial fuel cell
    38 , 11110-11116 [2013]
  • Effects of periodically alternating temperatures on performance of single-chamber microbial fuel cells
    39 , 8048-8054 . [2014]
  • Effects of high pH on the growth and survival of six marine heterotrophic protests
    260 , 33-41 [2003]
  • Effects of anode materials on electricity production from xylose and treatability of TMP wastewater in an up-flow microbial fuel cell
    372 , 141-150 [2019]
  • Effect of temperature on blue-green algae ( Cyanobacteria ) in Lake Mendota
    36 , 572-576 [1978]
  • Effect of temperature and light on the growth of algae species : A review
    50 , 431–444 . https : //doi.org/10.1016/j.rser.2015.05.024 [2015]
  • Effect of pH on nutrient dynamics and electricity production using microbial fuel cells
    101 , 9594-9599 [2010]
  • Effect of oxygen concentration on the growth of Nannochloropsis sp . at low light intensity
    24 , 863-871 [2012]
  • Effect of light on the production of bioelectricity and added-value microalgae biomass in a Photosynthetic Alga Microbial Fuel Cell
    [2014]
  • Effect of light intensity on the relative dominance of toxigenic and nontoxigenic strains of Microcystis aeruginosa
    77 , 7016-7022 [2011]
  • Effect of light intensity , pH , and temperature on triacylglycerol ( TAG ) accumulation induced by nitrogen starvation in Scenedesmus obliquus .
    143 , 1-9 . [2013]
  • Effect of electrolyte pH on the rate of the anodic and cathodic reactions in an air-cathode microbial fuel cell
    74 , 78-82 [2008]
  • Effect of dissolved oxygen on nitrogen and phosphorus removal and electricity production in microbial fuel cell .
    164 , 402–407 . https : //doi.org/https : //doi.org/10.1016/j.biortech.2014.05.002 [2014]
  • Effect of ammonia concentrations on growth of Chlorella vulgaris and nitrogen removal from media
    57:45-50 [1996]
  • Effect of algal species and light intensity on the performance of an air-lift-type microbial carbon capture cell with an algae-assisted cathode .
    6 , 25094-25100 . [2016]
  • Effect of Temperature Variation on the Performance of Microbial Fuel Cells
    5 , 2163-2167 [2017]
  • Economic assessment of an integrated bioethanol– biodiesel–microbial fuel cell facility utilizing yeast and photosynthetic algae
    87 , 1340-1348 [2009]
  • EFFECTS OF INORGANIC N AVAILABILITY ON ALGAL PHOTOSYNTHESIS ANDCARBON METABOLISM
    [1991]
  • Dong, H., Liu, X., Xu, T., Wang, Q., Chen, X., Chen, S., Zhang, H., Liang, P., Huang, X., Zhang, X., 2018. Hydrogen peroxide generation in microbial fuel cells using graphenebased air-cathodes. Bioresour. Technol. 247, 684-689. Du, Z., Li, H., Gu, T., 2007. A state of the art review on microbial fuel cells: A promising technology for wastewater treatment and bioenergy. Biotechnol. Adv. 25.
  • Directly applicable microbial fuel cells in aeration tank for wastewater treatment
    [2010]
  • Development of a model to determine mass transfer coefficient and oxygen solubility in bioreactors
    3 : e00248 . [2017]
  • Dai L. Carbon-based metal-free catalysts
    [2016]
  • Cost-effective Chlorella biomass production from dilute wastewater using a novel photosynthetic microbial fuel cell ( PMFC )
    10 , 356-364 [2016]
  • Correlation between Hydrogen Ion Concentration and Biota of Granite and Limestone Pools
    5 , 272-275 [2006]
  • Construction and operation of microbial fuel cell with Chlorella vulgaris biocathode for electricity generation
    171 , 2082-2092 [2013]
  • Comparison of electrogenic capabilities of microbial fuel cell with different light power on algae grown cathode .
    123 , 23-29 [2012]
  • Colprim J. Microbial fuel cell application in landfill leachate treatment
    185:763-7 [2011]
  • Charting our Water Future
    [2009]
  • Characterization of microalgae-bacteria consortium cultured in landfill leachate for carbon fixation and lipid production
    156:322-8 [2014]
  • Characterization of light/dark cycle and long-term performance test in a photosynthetic microbial fuel cell
    140 , 209-216 [2015]
  • Characterization of ionic conductivity profiles within proton exchange membrane fuel cell gas diffusion electrodes by impedance spectroscopy
    2:259-61 [1999]
  • Chapman, R.L., 2013. Algae: The world’s most important “plants”-an introduction. Mitig. Adapt. Strateg. Glob. Chang. https://doi.org/10.1007/s11027-010-9255-9
  • Carbon supported Cu-Sn bimetallic alloy as an excellent lowcost cathode catalyst for enhancing oxygen reduction reaction in microbial fuel cell
    165 ( 9 ) , F621-F628 .
  • Carbon dioxide sequestration accompanied by bioenergy generation using a bubbling-type photosynthetic algae microbial fuel cell
    280 , 95-103 . [2019]
  • Cai, P.J., Xiao, X., He, Y.R., Li, W.W., Zang, G.L., Sheng, G.P., Hon-Wah Lam, M., Yu, L., Yu, H.Q., 2013. Reactive oxygen species (ROS) generated by cyanobacteria act as an electron acceptor in the biocathode of a bio-electrochemical system. Biosens. Bioelectron. 39, 306-310.
  • C .. Electricity generation and removal performance of a microbial fuel cell using sulfonated poly ( ether ether ketone ) as proton exchange membrane to treat phenol/acetone wastewater
    260 , 130
  • Brush-like polyaniline nanoarray modified anode for improvement of power output in microbial fuel cell
    233 , 291-295 [2017]
  • Bioremediation of the textile waste effluent by Chlorella vulgaris
    40:301-8 [2014]
  • Biofouling inhibition and enhancing performance of microbial fuel cell using silver nano-particles as fungicide and cathode catalyst
    220 , 183-189
  • Bioelectrogenesis with microbial fuel cells ( MFCs ) using the microalga Chlorella vulgaris and bacterial communities
    31 , 34-43 . [2018]
  • Bioelectrochemical Energy Conversion
    12 , 10-12 . [1964]
  • Binary biosorption of cadmium ( II ) and nickel ( II ) onto dried Chlorella vulgaris : Coion effect on mono-component isotherm parameters .
    41 , 860-868 . [2006]
  • BP Energy Outlook Energy 2017
    [2017]
  • Assisting cultivation of photosynthetic microorganisms by microbial fuel cells to enhance nutrients recovery from wastewater
    237 , 240-248 [2017]
  • Appreciating the role of carbon nanotube composites in preventing biofouling and promoting biofilms on material surfaces in environmental engineering : A review
    28 , 802-816 [2010]
  • Applications of graphene-modified electrodes in microbial fuel cells
    9 , 1-27 . [2016]
  • Applications of graphene in microbial fuel cells : The gap between promise and reality
    72 , 1389-1403 [2017]
  • Angelaalincy, M.J., Navanietha Krishnaraj, R., Shakambari, G., Ashokkumar, B., Kathiresan, S., Varalakshmi, P., 2018. Biofilm Engineering Approaches for Improving the Performance of Microbial Fuel Cells and Bioelectrochemical Systems. Front. Energy Res. 6, 63. https://doi.org/10.3389/fenrg.2018.00063 0 1 2 3 4 5 6 7 8 9 10 -0.60 -0.50 -0.40 -0.30 -0.20 -0.10 0.00 0.10 0.20 0.30 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 DO concentration (mg/L) Voltage (V) Time (days) Cell voltage Anode potential Cathode potential DO concentration 77.1 h 25.7 h 19.3 h 6.4 h136
  • Analysis of ammonia loss mechanisms in microbial fuel cells treating animal wastewater
    99:1120-7 [2008]
  • Anaerobic conversion of microalgal biomass to sustainable energy carriers - A review
    135 , 222-231 . [2013]
  • An investigation of anode and cathode materials in photomicrobial fuel cells
    374 , 1-22 [2016]
  • Algal-microbial community collaboration for energy recovery and nutrient remediation from wastewater in integrated photobioelectrochemical systems
    24 , 527-539 [2017]
  • Algal growth in photosynthetic algal microbial fuel cell and its subsequent utilization for biofuels .
    82 , 402-414 [2018]
  • Algal biofilm-assisted microbial fuel cell to enhance domestic wastewater treatment : Nutrient , organics removal and bioenergy production
    332 , 277-285 [2018]
  • Algal biofilm based technology for wastewater treatment
    5 , 231-240 [2014]
  • Algal biocathodes . ‘ Microbial Electrochemical Technology : Platform for Fuels , Chemicals and Remediation ’ . Biomass , Biofuels and Biochemicals . Elsevier . S. Venkata Mohan . et al . ( eds . )
    [2019]
  • Algal biocathode for in situ terminal electron acceptor ( TEA ) production : Synergetic association of bacteria-microalgae metabolism for the functioning of biofuel cell
    166 , 566-574 . [2014]
  • Algae cathode microbial fuel cells for electricity generation and nutrient removal from landfill leachate wastewater
    42 , 29433-29442 [2017]
  • Algae cathode microbial fuel cells for cadmium removal with simultaneous electricity production using nickel foam/graphene electrode .
    138 , 179-187 . [2018]
  • Advanced wastewater treatment using microalgae : effect of temperature on removal of nutrients and organic carbon
    67 , 1-7 [2017]
  • Activated carbon from lignocellulosics precursors : A review of the synthesis methods , characterization techniques and applications
    82 , 1393-1414 [2018]
  • Acclimation and toxicity of high ammonium concentrations to unicellular algae
    80:8-23 [2014]
  • Abinandan, S., Shanthakumar, S., 2015. Challenges and opportunities in application of microalgae (Chlorophyta) for wastewater treatment: A review. Renew. Sustain. Energy Rev. 52, 123–132. https://doi.org/10.1016/j.rser.2015.07.086
  • A synergistic use of microalgae and macroalgae for heavy metal bioremediation and bioenergy production through hydrothermal liquefaction
    3 , 292-301 . [2019]
  • A review of the substrates used in microbial fuel cells ( MFCs ) for sustainable energy production
    101 , 1533-1543 [2010]
  • A photosynthetic algal microbial fuel cell for treating swine wastewater .
    26 , 6182-6190 [2019]
  • A microbial fuel cell with a photosynthetic microalgae cathodic half-cell coupled to a yeast anodic half-cell
    33 , 440-448 . [2011]
  • A critical review on microalgae as an alternative source for bioenergy production : A promising low cost substrate for microbial fuel cells
    154 , 104-116 [2016]
  • A bio-electrochemical membrane system for more sustainable wastewater treatment with MnO2/PANI modified stainless steel cathode and photosynthetic provision of dissolved oxygen by algae
    76 , 1907- 1914 [2017]