| A pseudo three-dimensional electrochemical–thermal model of a prismatic LiFePO4 battery during discharge process M Xu, Z Zhang, X Wang, L Jia, L Yang Energy 80, 303-317, 2015 | 250 | 2015 |
| Three-dimensional modeling and experimental study of a high temperature PBI-based PEM fuel cell EU Ubong, Z Shi, X Wang Journal of The Electrochemical Society 156 (10), B1276, 2009 | 239 | 2009 |
| Investigation of bio-inspired flow channel designs for bipolar plates in proton exchange membrane fuel cells JP Kloess, X Wang, J Liu, Z Shi, L Guessous Journal of Power Sources 188 (1), 132-140, 2009 | 230 | 2009 |
| Two-dimensional electrochemical–thermal coupled modeling of cylindrical LiFePO4 batteries M Xu, Z Zhang, X Wang, L Jia, L Yang Journal of power sources 256, 233-243, 2014 | 161 | 2014 |
| Experimental investigation of pulsating heat pipe performance with regard to fuel cell cooling application J Clement, X Wang Applied Thermal Engineering 50 (1), 268-274, 2013 | 155 | 2013 |
| Fast charging optimization for lithium-ion batteries based on dynamic programming algorithm and electrochemical-thermal-capacity fade coupled model M Xu, R Wang, P Zhao, X Wang Journal of Power Sources 438, 227015, 2019 | 145 | 2019 |
| Experimental study on the influence of temperature and state-of-charge on the thermophysical properties of an LFP pouch cell SJ Bazinski, X Wang Journal of Power Sources 293, 283-291, 2015 | 127 | 2015 |
| Modeling the effect of electrode thickness on the performance of lithium-ion batteries with experimental validation M Xu, B Reichman, X Wang Energy 186, 115864, 2019 | 101 | 2019 |
| Separation criterion for turbulent boundary layers via similarity analysis L Castillo, X Wang, WK George J. Fluids Eng. 126 (3), 297-304, 2004 | 98 | 2004 |
| A numerical study of flow crossover between adjacent flow channels in a proton exchange membrane fuel cell with serpentine flow field Z Shi, X Wang Journal of power sources 185 (2), 985-992, 2008 | 84 | 2008 |
| The influence of cell temperature on the entropic coefficient of a lithium iron phosphate (LFP) pouch cell SJ Bazinski, X Wang Journal of The Electrochemical Society 161 (1), A168, 2013 | 71 | 2013 |
| Modeling the effect of two-stage fast charging protocol on thermal behavior and charging energy efficiency of lithium-ion batteries M Xu, R Wang, B Reichman, X Wang Journal of energy storage 20, 298-309, 2018 | 70 | 2018 |
| Effect of compression on the water management of a proton exchange membrane fuel cell with different gas diffusion layers Z Shi, X Wang, L Guessous | 56 | 2010 |
| Design of an optical thermal sensor for proton exchange membrane fuel cell temperature measurement using phosphor thermometry K Inman, X Wang, B Sangeorzan Journal of Power Sources 195 (15), 4753-4757, 2010 | 50 | 2010 |
| Predicting heat generation in a lithium-ion pouch cell through thermography and the lumped capacitance model SJ Bazinski, X Wang Journal of Power Sources 305, 97-105, 2016 | 43 | 2016 |
| Comparison of Darcy’s law, the Brinkman equation, the modified NS equation and the pure diffusion equation in PEM fuel cell modeling Z Shi, X Wang COMSOL conference, 2007 | 42 | 2007 |
| Measuring and assessing the effective in-plane thermal conductivity of lithium iron phosphate pouch cells SJ Bazinski, X Wang, BP Sangeorzan, L Guessous Energy 114, 1085-1092, 2016 | 41 | 2016 |
| Temperature scalings and profiles in forced convection turbulent boundary layers X Wang, L Castillo, G Araya | 41 | 2008 |
| Asymptotic solutions in forced convectionturbulent boundary layers X Wang, L Castillo Journal of Turbulence 4 (1), 006, 2003 | 36 | 2003 |
| Similarity analysis for nonequilibrium turbulent boundary layers L Castillo, X Wang J. Fluids Eng. 126 (5), 827-834, 2004 | 35 | 2004 |
Luciano CastilloPurdue UniversityVerified email at purdue.edu