| Predicting active material utilization in LiFePO4 electrodes using a multiscale mathematical model S Dargaville, TW Farrell Journal of the Electrochemical Society 157 (7), A830, 2010 | 140 | 2010 |
| Mathematical model for intermittent microwave convective drying of food materials C Kumar, MUH Joardder, TW Farrell, GJ Millar, MA Karim Drying Technology 34 (8), 962-973, 2016 | 102 | 2016 |
| Multiphase porous media model for intermittent microwave convective drying (IMCD) of food C Kumar, MUH Joardder, TW Farrell, MA Karim International Journal of Thermal Sciences 104, 304-314, 2016 | 102 | 2016 |
| Micropolar flow over a porous stretching sheet with strong suction or injection NA Kelson, TW Farrell International Communications in Heat and Mass Transfer 28 (4), 479-488, 2001 | 74 | 2001 |
| A physics-based distributed-parameter equivalent circuit model for lithium-ion batteries Y Li, M Vilathgamuwa, T Farrell, NT Tran, J Teague Electrochimica Acta 299, 451-469, 2019 | 44 | 2019 |
| Primary Alkaline Battery Cathodes A Three‐Scale Model TW Farrell, CP Please, DLS McElwain, DAJ Swinkels Journal of the Electrochemical Society 147 (11), 4034, 2000 | 39 | 2000 |
| A mathematical model for the anodic half cell of a dye-sensitised solar cell M Penny, T Farrell, G Will Solar energy materials and solar cells 92 (1), 24-37, 2008 | 38 | 2008 |
| The persistence of phase-separation in LiFePO4 with two-dimensional Li+ transport: The Cahn–Hilliard-reaction equation and the role of defects S Dargaville, TW Farrell Electrochimica Acta 94, 143-158, 2013 | 37 | 2013 |
| Investigation of intermittent microwave convective drying (IMCD) of food materials by a coupled 3D electromagnetics and multiphase model C Kumar, MUH Joardder, TW Farrell, MA Karim Drying Technology 36 (6), 736-750, 2018 | 32 | 2018 |
| A comparison of mathematical models for phase-change in high-rate LiFePO4 cathodes S Dargaville, TW Farrell Electrochimica Acta 111, 474-490, 2013 | 31 | 2013 |
| Optimal catalyst thickness in titanium dioxide fixed film reactors: Mathematical modelling and experimental validation M Vezzoli, T Farrell, A Baker, S Psaltis, WN Martens, JM Bell Chemical engineering journal 234, 57-65, 2013 | 29 | 2013 |
| Mathematical modelling and numerical simulation of phosphine flow during grain fumigation in leaky cylindrical silos ZM Isa, TW Farrell, GR Fulford, NA Kelson Journal of Stored Products Research 67, 28-40, 2016 | 28 | 2016 |
| A mathematical model for interfacial charge transfer at the semiconductor–dye–electrolyte interface of a dye-sensitised solar cell M Penny, T Farrell, C Please Solar Energy Materials and Solar Cells 92 (1), 11-23, 2008 | 28 | 2008 |
| Development of a degradation-conscious physics-based lithium-ion battery model for use in power system planning studies Y Li, M Vilathgamuwa, TW Farrell, NT Tran, J Teague Applied Energy 248, 512-525, 2019 | 27 | 2019 |
| A porous media transport model for apple drying C Kumar, MUH Joardder, TW Farrell, GJ Millar, A Karim Biosystems engineering 176, 12-25, 2018 | 27 | 2018 |
| Comparing charge transport predictions for a ternary electrolyte using the Maxwell–Stefan and Nernst–Planck equations STP Psaltis, TW Farrell Journal of The Electrochemical Society 158 (1), A33, 2010 | 27 | 2010 |
| Comparing charge transport predictions for a ternary electrolyte using the Maxwell–Stefan and Nernst–Planck equations STP Psaltis, TW Farrell Journal of The Electrochemical Society 158 (1), A33, 2010 | 27 | 2010 |
| Comparing Charge Transport Predictions for a Ternary Electrolyte using the Maxwell-Stefan and Nernst-Planck Equations SPTW Farrell J. Electrochem. Soc. 158 (1), A33-A42, 2010 | 27 | 2010 |
| Micropolar flow in a porous channel with high mass transfer NA Kelson, A Desseaux, TW Farrell ANZIAM Journal 44, C479-C495, 2002 | 26 | 2002 |
| Primary alkaline battery cathodes: A simplified model for porous manganese oxide particle discharge TW Farrell, CP Please Journal of The Electrochemical Society 152 (10), A1930, 2005 | 25 | 2005 |
Colin PleaseProfessor of Applied Mathematics, University of OxfordZweryfikowany adres z maths.ox.ac.uk
