| Urea electrolysis: direct hydrogen production from urine BK Boggs, RL King, GG Botte Chemical Communications, 4859-4861, 2009 | 673 | 2009 |
| Understanding the electro-catalytic oxidation mechanism of urea on nickel electrodes in alkaline medium V Vedharathinam, GG Botte Electrochimica Acta 81, 292-300, 2012 | 462 | 2012 |
| On the use of ammonia electrolysis for hydrogen production F Vitse, M Cooper, GG Botte Journal of Power Sources 142 (1-2), 18-26, 2005 | 410 | 2005 |
| Direct evidence of the mechanism for the electro-oxidation of urea on Ni (OH) 2 catalyst in alkaline medium V Vedharathinam, GG Botte Electrochimica Acta 108, 660-665, 2013 | 387 | 2013 |
| Mathematical modeling of secondary lithium batteries GG Botte, VR Subramanian, RE White Electrochimica Acta 45 (15-16), 2595-2609, 2000 | 366 | 2000 |
| Nickel and cobalt bimetallic hydroxide catalysts for urea electro-oxidation W Yan, D Wang, GG Botte Electrochimica Acta 61, 25-30, 2012 | 334 | 2012 |
| Dissociation rates of urea in the presence of NiOOH catalyst: a DFT analysis DA Daramola, D Singh, GG Botte The Journal of Physical Chemistry A 114 (43), 11513-11521, 2010 | 300 | 2010 |
| Electrochemical decomposition of urea with Ni-based catalysts W Yan, D Wang, GG Botte Applied Catalysis B: Environmental 127, 221-226, 2012 | 294 | 2012 |
| Recycling of graphite anodes for the next generation of lithium ion batteries B Moradi, GG Botte Journal of Applied Electrochemistry 46, 123-148, 2016 | 281 | 2016 |
| Thermal stability of LiPF6–EC: EMC electrolyte for lithium ion batteries GG Botte, RE White, Z Zhang Journal of Power Sources 97, 570-575, 2001 | 232 | 2001 |
| Investigation of multi-metal catalysts for stable hydrogen production via urea electrolysis RL King, GG Botte Journal of Power Sources 196 (22), 9579-9584, 2011 | 227 | 2011 |
| Enhanced electrocatalytic oxidation of urea based on nickel hydroxide nanoribbons D Wang, W Yan, SH Vijapur, GG Botte Journal of power sources 217, 498-502, 2012 | 210 | 2012 |
| Electrochemically reduced graphene oxide–nickel nanocomposites for urea electrolysis D Wang, W Yan, SH Vijapur, GG Botte Electrochimica Acta 89, 732-736, 2013 | 203 | 2013 |
| Electrochemical manufacturing in the chemical industry GG Botte The Electrochemical Society Interface 23 (3), 49, 2014 | 199 | 2014 |
| Influence of some design variables on the thermal behavior of a lithium‐ion cell GG Botte, BA Johnson, RE White Journal of the Electrochemical Society 146 (3), 914, 1999 | 192 | 1999 |
| On-board hydrogen storage and production: An application of ammonia electrolysis BK Boggs, GG Botte Journal of Power Sources 192 (2), 573-581, 2009 | 188 | 2009 |
| Effect of catalyst on electrolysis of ammonia effluents EP Bonnin, EJ Biddinger, GG Botte Journal of Power Sources 182 (1), 284-290, 2008 | 187 | 2008 |
| Nickel nanowires as effective catalysts for urea electro-oxidation W Yan, D Wang, LA Diaz, GG Botte Electrochimica Acta 134, 266-271, 2014 | 168 | 2014 |
| Exfoliated nickel hydroxide nanosheets for urea electrolysis D Wang, W Yan, GG Botte Electrochemistry communications 13 (10), 1135-1138, 2011 | 168 | 2011 |
| Optimization of Pt–Ir on carbon fiber paper for the electro-oxidation of ammonia in alkaline media BK Boggs, GG Botte Electrochimica Acta 55 (19), 5287-5293, 2010 | 164 | 2010 |