Pee power urinal–microbial fuel cell technology field trials in the context of sanitation IA Ieropoulos, A Stinchcombe, I Gajda, S Forbes, I Merino-Jimenez, ... Environmental Science: Water Research & Technology 2 (2), 336-343, 2016 | 220 | 2016 |
Developments in direct borohydride fuel cells and remaining challenges I Merino-Jiménez, CP De León, AA Shah, FC Walsh Journal of Power Sources 219, 339-357, 2012 | 212 | 2012 |
PEE POWER® urinal II – Urinal scale-up with microbial fuel cell scale-down for improved lighting XA Walter, I Merino-Jiménez, J Greenman, I Ieropoulos Journal of Power Sources 392, 150-158, 2018 | 135 | 2018 |
Enhanced MFC power production and struvite recovery by the addition of sea salts to urine I Merino-Jimenez, V Celorrio, DJ Fermin, J Greenman, I Ieropoulos Water research 109, 46-53, 2017 | 117 | 2017 |
Carbon-based air-breathing cathodes for microbial fuel cells I Merino-Jimenez, C Santoro, S Rojas-Carbonell, J Greenman, ... Catalysts 6 (9), 127, 2016 | 79 | 2016 |
Miniaturised ceramic-based microbial fuel cell for efficient power generation from urine and stack development I Gajda, A Stinchcombe, I Merino-Jimenez, G Pasternak, ... Frontiers in Energy Research 6 (84), 2018 | 68 | 2018 |
Ceramic Microbial Fuel Cells Stack: power generation in standard and supercapacitive mode C Santoro, C Flores-Cadengo, F Soavi, M Kodali, I Merino-Jimenez, ... Scientific reports 8 (1), 3281, 2018 | 67 | 2018 |
Electricity and catholyte production from ceramic MFCs treating urine IM Jimenez, J Greenman, I Ieropoulos international journal of hydrogen energy 42 (3), 1791-1799, 2017 | 65 | 2017 |
Pd–Ir alloy as an anode material for borohydride oxidation I Merino-Jimenez, MJ Janik, CP De Leon, FC Walsh Journal of Power Sources 269, 498-508, 2014 | 59 | 2014 |
Increased power generation in supercapacitive microbial fuel cell stack using FeNC cathode catalyst C Santoro, M Kodali, N Shamoon, A Serov, F Soavi, I Merino-Jimenez, ... Journal of Power Sources 412, 416-424, 2019 | 48 | 2019 |
Microbial Desalination Cells with Efficient Platinum‐Group‐Metal‐Free Cathode Catalysts C Santoro, MR Talarposhti, M Kodali, R Gokhale, A Serov, ... ChemElectroChem 4 (12), 3322-3330, 2017 | 48 | 2017 |
Improvements in direct borohydride fuel cells using three-dimensional electrodes CP De León, A Kulak, S Williams, I Merino-Jiménez, FC Walsh Catalysis today 170 (1), 148-154, 2011 | 37 | 2011 |
Effect of the ceramic membrane properties on the microbial fuel cell power output and catholyte generation I Merino-Jimenez, F Gonzalez-Juarez, J Greenman, I Ieropoulos Journal of Power Sources 429, 30-37, 2019 | 32 | 2019 |
The effect of surfactants on the kinetics of borohydride oxidation and hydrolysis in the DBFC I Merino-Jimenez, CP de Leon, FC Walsh Electrochimica Acta 133, 539-545, 2014 | 25 | 2014 |
Electrocatalyst design for direct borohydride oxidation guided by first principles G Rostamikia, RJ Patel, I Merino-Jimenez, M Hickner, MJ Janik The Journal of Physical Chemistry C 121 (5), 2872-2881, 2017 | 17 | 2017 |
Investigation of the use of sodium borohydride for fuel cells I Merino Jimenez University of Southampton, 2013 | 1 | 2013 |
Field Trial of Self-Stratifying Membrane-Less Microbial Fuel Cells Stacks in an Autonomous and Self-Powered Urinal XA Walter, I Merino-Jimenez, J Greenman, I Ieropoulos Meeting Abstracts, 2266-2266, 2018 | | 2018 |
Developments in Electrodes, Membranes, and Electrolytes for Direct Borohydride Fuel Cells I Merino-Jiménez, CP de León, FC Walsh Advanced Materials for Clean Energy, 602-619, 2015 | | 2015 |