| Ammonia synthesis by N2 and steam electrolysis in molten hydroxide suspensions of nanoscale Fe2O3 S Licht, B Cui, B Wang, FF Li, J Lau, S Liu Science 345 (6197), 637-640, 2014 | 735 | 2014 |
| Efficient Solar Water Splitting, Exemplified by RuO2-Catalyzed AlGaAs/Si Photoelectrolysis S Licht, B Wang, S Mukerji, T Soga, M Umeno, H Tributsch The Journal of Physical Chemistry B 104 (38), 8920-8924, 2000 | 499 | 2000 |
| Energetic iron (VI) chemistry: The super-iron battery S Licht, B Wang, S Ghosh Science 285 (5430), 1039-1042, 1999 | 408 | 1999 |
| Solar hydrogen generation K Rajeshwar, R McConnell, S Licht Springer, 2008 | 327 | 2008 |
| A solid sulfur cathode for aqueous batteries D Peramunage, S Licht Science 261 (5124), 1029-1032, 1993 | 307 | 1993 |
| The fundamental conductivity and resistivity of water TS Light, S Licht, AC Bevilacqua, KR Morash Electrochemical and solid-state letters 8 (1), E16, 2004 | 281 | 2004 |
| Over 18% solar energy conversion to generation of hydrogen fuel; theory and experiment for efficient solar water splitting S Licht, B Wang, S Mukerji, T Soga, M Umeno, H Tributsch International journal of hydrogen energy 26 (7), 653-659, 2001 | 255 | 2001 |
| One-Pot Synthesis of Carbon Nanofibers from CO2 J Ren, FF Li, J Lau, L González-Urbina, S Licht Nano letters 15 (9), 6142-6148, 2015 | 251 | 2015 |
| Photoelectrochemistry and Hybrid Solar Conversion S Licht Fundamentals of Materials for Energy and Environmental Sustainability, 692-710, 2011 | 220* | 2011 |
| Multiple band gap semiconductor/electrolyte solar energy conversion S Licht The Journal of Physical Chemistry B 105 (27), 6281-6294, 2001 | 218 | 2001 |
| Multiple Bandgap Semiconductor/Electrolyte Solar Energy Conversion S Licht The Journal of Physical Chemistry B 105 (27), 6281–6294, 2001 | 218 | 2001 |
| Aqueous solubilities, solubility products and standard oxidation‐reduction potentials of the metal sulfides S Licht Journal of the Electrochemical Society 135 (12), 2971, 1988 | 206 | 1988 |
| Solar Thermal and Efficient Solar Thermal/Electrochemical Photo Hydrogen Generation S Licht On Solar Hydrogen & Nanotechnology, 641-664, 2010 | 200* | 2010 |
| Analysis of ferrate (VI) compounds and super-iron Fe (VI) battery cathodes: FTIR, ICP, titrimetric, XRD, UV/VIS, and electrochemical characterization S Licht, V Naschitz, L Halperin, N Halperin, L Lin, J Chen, S Ghosh, B Liu Journal of Power Sources 101 (2), 167-176, 2001 | 193 | 2001 |
| Carbon nanotubes produced from ambient carbon dioxide for environmentally sustainable lithium-ion and sodium-ion battery anodes S Licht, A Douglas, J Ren, R Carter, M Lefler, CL Pint ACS central science 2 (3), 162-168, 2016 | 190 | 2016 |
| A new solar carbon capture process: solar thermal electrochemical photo (STEP) carbon capture S Licht, B Wang, S Ghosh, H Ayub, D Jiang, J Ganley The Journal of Physical Chemistry Letters 1 (15), 2363-2368, 2010 | 181 | 2010 |
| Semiconductor Electrodes and Photoelectrochemistry S Licht (No Title) 6, 2002 | 168 | 2002 |
| A light-variation insensitive high efficiency solar cell S Licht, G Hodes, R Tenne, J Manassen Nature 326 (6116), 863-864, 1987 | 161 | 1987 |
| Electrolyte modified photoelectrochemical solar cells S Licht Solar Energy Materials and solar cells 38 (1-4), 305-319, 1995 | 158 | 1995 |
| Efficient solar‐driven synthesis, carbon capture, and desalinization, STEP: solar thermal electrochemical production of fuels, metals, bleach S Licht Advanced materials 23 (47), 5592-5612, 2011 | 151 | 2011 |
