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References
|
Belleville P, Strong P, Dare P, Gapes D (2011). Influence of nitrogen limitation on performance of a microbial fuel cell. Water Science and Technology 63(8):1752-1757. |
|
|
Cai L, White R (2011). Mathematical modelling of a lithium-ion battery with thermal effects in COMSOL Inc. Multiphysics (MP) software. Journal of Power Sources, 196(14):5985-5989. |
|
|
Chaudhuri S, Lovley D (2003). Electricity generation by direct oxidation of glucose in mediatorless microbial fuel cells. Nature Biotechnology 21(10):1229-1232. |
|
|
Chen, C, Chen T, Chung Y (2013). A comparison of bioelectricity in microbial fuel cells with aerobic and anaerobic anodes. Environmental Technology, 35(3):286-293. |
|
|
Cœuret F, Vilar E, Cavalcanti E (2002). Carbon fibre cloth as an electrode material: electrical conductivity and mass transfer . Journal of Applied Electrochemistry 32(10):1175-1182. |
|
|
Dumas C, Mollica A, Féron D, Basseguy R, Etcheverry L, Bergel A (2008). Checking graphite and stainless anodes with an experimental model of marine microbial fuel cell. Bioresource Technology 99(18):8887-8894. |
|
|
Ghasemi M, Daud W, Hassan S, Oh S, Ismail M, Rahimnejad M, Jahim J (2013). Nano-structured carbon as electrode material in microbial fuel cells: A comprehensive review. Journal of Alloys and Compounds 580:245-255. |
|
|
Gude V (2016). Wastewater treatment in microbial fuel cells - an overview. Journal of Cleaner Production 122:287-307. |
|
|
Haque E, Rahaman M (2021). First-principles prediction of structural stability and thermoelectric properties of SrGaSnH. RSC Advances 11:3304-3314 |
|
|
Hernández-Flores G, Poggi-Varaldo HM, Solorza-Feria O, Ponce Noyola MT, Romero-Castañón T, Rinderknecht-Seijas N (2015). Tafel Equation Based Model for the Performance of a Microbial Fuel Cell. International Journal of Hydrogen Energy 40(48):17421-17432. |
|
|
Hossain A (2020). Development of a physics-based mathematical model of microparticle silicon based lithium half cells. |
|
|
Hossain A (2021). Development of a Mathematical Model to Study the Impact of State of Charge Dependent Exchange Current Density on the Generated Voltage Hysteresis of Silicon Anode-based Lithium Half Cells. Journal of Mechanical Engineering Research 12(1):37-48. |
|
|
Hossain A, Cha Y, Song M, Kim S (2020). Side Reaction Correction and Non-linear Exchange Current Density for Mathematical Modelling of Silicon Anode Based Lithium-Ion Batteries. |
|
|
Hossain A, Kim S (2020). Development of a physics-based mathematical model to analyse the limitations of microparticle silicon-based lithium half cells. IMECE Technical Presentation. |
|
|
Hossain A, Masud N, Yasin M, Ali M (2020). Analysis of the Performance of Microbial Fuel Cell as a Potential Energy Storage Device. Proceedings of International Exchange and Innovation Conference on Engineering and Sciences 6(6):149-155. |
|
|
Hossain A, Masud N, Ali M (2022). Comprehensive cost analysis of electrochemical performance in microbial fuel cells. Microbial Fuel Cells: Emerging Trends in Electrochemical Applications 1:350 |
|
|
Li F, Sharma Y, Lei Y, Li B, Zhou Q (2009). Microbial Fuel Cells: The Effects of Configurations, Electrolyte Solutions, and Electrode Materials on Power Generation. Applied Biochemistry and Biotechnology 160(1):168-181. |
|
|
Liu H, Logan B (2004). Electricity Generation Using an Air-Cathode Single Chamber Microbial Fuel Cell in the Presence and Absence of a Proton Exchange Membrane. Environmental Science and Technology 38(14):4040-4046. |
|
|
Liu J, Qiao Y, Guo C, Lim S, Song H, Li C (2012). Graphene/carbon cloth anode for high-performance mediator-less microbial fuel cells. Bioresource Technology 114: 275-280. |
|
|
Liu X, and Cheema I (2012). Managing Process Streams at Sjölunda WWTP with Electricity- Producing Bacteria Investigation of Alkalinity Redistribution and Maximum Current Generation Capacity in Bio electrochemical Systems. Department of Chemical Engineering, Lund University, Sweden. |
|
|
Logan B, Regan J (2006). Microbial Fuel Cells-Challenges and Applications. Environmental Science & Technology, 40(17):5172-5180. |
|
|
Logan B, Hamelers B, Rozendal R, Schröder U, Keller J, Freguia S, Aelterman P, Verstraete W, and Rabaey K (2006). Microbial Fuel Cells: Methodology and Technology. Environmental Science and Technology, 40 (17):5181-5192. |
|
|
Lu Z, Chang D, Ma J, Huang G, Cai L, and Zhang L (2015). Behavior of metal ions in bioelectrochemical systems: A review. Journal of Power Sources 275:243-260. |
|
|
Masud N, Hossain A, Moresalein M, Ali M (2021). Performance Evaluation of Microbial Fuel Cell with Food Waste Solution as a Potential Energy Storage Medium. Proceedings of International Exchange and Innovation Conference on Engineering and Sciences 7:96-102. |
|
|
Miah M, Majumder A, and Latifa G (2017). Evaluation of microbial quality of the surface water of Hatirjheel in Dhaka City. Stamford Journal of Microbiology 6(1):30-33. |
|
|
Min B, Logan B (2004). Continuous Electricity Generation from Domestic Wastewater and Organic Substrates in a Flat Plate Microbial Fuel Cell. Environmental Science and Technology 38(21):5809-5814. |
|
|
Min B, Cheng S, Logan B (2005). "Electricity generation using membrane and salt bridge microbial fuel cells. Water Research 39(9):1675-1686. |
|
|
Oh S, Logan B (2005). Hydrogen and electricity production from a food processing wastewater using fermentation and microbial fuel cell technologies. Water Research 39(19):4673-4682. |
|
|
Ojeda B, Waliullah M, Hossain A, Nguyen T, Wettstein T, Tadesse Y, Bernal R (2022). High-throughput tensile testing of silver nanowires (2022). Extreme Mechanics Letters 56:101896 |
|
|
Oliveira V, Simões M., Melo L, Pinto A (2013). A 1D mathematical model for a microbial fuel cell. Energy 61:463-471. |
|
|
Pinto R, Srinivasan B, Manuel M, Tartakovsky B (2010). A two-population bio-electrochemical model of a microbial fuel cell. Bioresource Technology 101(14):5256-5265. |
|
|
Rahimnejad M, Adhami A, Darvari S, Zirepour A, Oh S (2015). Microbial fuel cell as new technology for bioelectricity generation: A review. Alexandria Engineering Journal 54(3):745-756. |
|
|
Rosenberg B, Van Camp L, and Krigas T (1965). Inhibition of Cell Division in Escherichia coli by Electrolysis Products from a Platinum Electrode. Nature, 205(4972):698-699. |
|
|
Tariquzzaman S, Nishu S, Saeed T, Ahmed R (2016). Water Quality and EIA of Simple Hatirjheel Lake. Conference: Proceedings of the 3rd International Conference on Civil Engineering for Sustainable Development (ICCESD). |
|
|
Valdez-Vazquez I, Ríos-Leal E, Carmona-Martínez A, Muñoz-Páez K, Poggi-Varaldo H (2006). Improvement of Biohydrogen Production from Solid Wastes by Intermittent Venting and Gas Flushing of Batch Reactors Headspace. Environmental Science and Technology 40(10):3409-3415. |
|
|
Valo?en L, Reimers J (2005). Transport Properties of LiPF6 -Based Li-Ion Battery Electrolytes. Journal of the Electrochemical Society 152(5):A882-892. |
|
|
Walter X, Forbes S, Greenman J, Ieropoulos I (2016). From single MFC to cascade configuration: The relationship between size, hydraulic retention time and power density. Sustainable Energy Technologies and Assessments 14:74-79. |
|
|
Wei J, Liang P, Huang X (2011). Recent progress in electrodes for microbial fuel cells. Bioresource Technology, 102(20):9335-9344. |
|
|
Yang C (2009). An impending platinum crisis and its implications for the future of the automobile. Energy Policy 37(5):1805-1808. |
|
|
Zeng Y, Choo Y, Kim B, Wu P (2010). Modelling and simulation of two-chamber microbial fuel cell. Journal of Power Sources 195(1):79-89. |
|
|
Zhang Y, Mo G, Li X, Zhang W, Zhang J, Ye J, Huang X, Yu C (2011). A graphene modified anode to improve the performance of microbial fuel cells. Journal of Power Sources 196(13):5402-5407. |
|
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