| 1 |
Review of necessary thermophysical properties and their sensivities with temperature and electrolyte mass fractions for alkaline water electrolysis multiphysics modelling
Le Bideau D, Mandin P, Benbouzid M, Kim M, Sellier M
International Journal of Hydrogen Energy, 44(10), 4553, 2019 |
| 2 |
Three-dimensional multiphysics model of a planar solid oxide fuel cell using computational fluid dynamics approach
Celik AN
International Journal of Hydrogen Energy, 43(42), 19730, 2018 |
| 3 |
Multiphysics modelling and experimental validation of high concentration photovoltaic modules
Theristis M, Fernandez EF, Sumner M, O'Donovan TS
Energy Conversion and Management, 139, 122, 2017 |
| 4 |
Development of an experimentally validated semi-empirical fully-coupled performance model of a PEM electrolysis cell with a 3-D structured porous transport layer
Ojong ET, Kwan JTH, Nouri-Khorasani A, Bonakdarpour A, Wilkinson DP, Smolinka T
International Journal of Hydrogen Energy, 42(41), 25831, 2017 |
| 5 |
Reverse engineering of a railcar prototype via energetic macroscopic representation approach
Agbli KS, Hissel D, Sorrentino M, Chauvet F, Pouget J
Energy Conversion and Management, 112, 61, 2016 |
| 6 |
Improving the design of gas diffusion layers for intermediate temperature polymer electrolyte fuel cells using a sensitivity analysis: A multiphysics approach
Chandan A, Rees NV, Steinberger-Wilckens R, Self V, Richmond J
International Journal of Hydrogen Energy, 40(46), 16745, 2015 |
| 7 |
A 3D transient nonlinear modelling of coupled heat, mass and deformation fields in anisotropic material
Trcala M
International Journal of Heat and Mass Transfer, 55(17-18), 4588, 2012 |
| 8 |
Electrochemical microfluidics
Zimmerman WB
Chemical Engineering Science, 66(7), 1412, 2011 |
| 9 |
Multiphysics simulation of a PEM electrolyser: Energetic Macroscopic Representation approach
Agbli KS, Pera MC, Hissel D, Rallieres O, Turpin C, Doumbia I
International Journal of Hydrogen Energy, 36(2), 1382, 2011 |
