| Thin film photoelectrodes for solar water splitting Y He, T Hamann, D Wang Chemical Society Reviews 48 (7), 2182-2215, 2019 | 256 | 2019 |
| What limits the performance of Ta3N5 for solar water splitting? Y He, JE Thorne, CH Wu, P Ma, C Du, Q Dong, J Guo, D Wang Chem 1 (4), 640-655, 2016 | 169 | 2016 |
| Comparison of heterogenized molecular and heterogeneous oxide catalysts for photoelectrochemical water oxidation W Li, D He, SW Sheehan, Y He, JE Thorne, X Yao, GW Brudvig, D Wang Energy & Environmental Science 9 (5), 1794-1802, 2016 | 149 | 2016 |
| Hematite‐based solar water splitting in acidic solutions: functionalization by mono‐and multilayers of iridium oxygen‐evolution catalysts W Li, SW Sheehan, D He, Y He, X Yao, RL Grimm, GW Brudvig, D Wang Angewandte Chemie 127 (39), 11590-11594, 2015 | 142 | 2015 |
| Forming buried junctions to enhance the photovoltage generated by cuprous oxide in aqueous solutions P Dai, W Li, J Xie, Y He, J Thorne, G McMahon, J Zhan, D Wang Angewandte Chemie 126 (49), 13711-13715, 2014 | 135 | 2014 |
| Enabling practical electrocatalyst-assisted photoelectron-chemical water splitting with earth abundant materials X Yang, R Liu, Y He, J Thorne, Z Zheng, D Wang Nano research 8, 56-81, 2015 | 100 | 2015 |
| Cathodically stable Li-O2 battery operations using water-in-salt electrolyte Q Dong, X Yao, Y Zhao, M Qi, X Zhang, H Sun, Y He, D Wang Chem 4 (6), 1345-1358, 2018 | 85 | 2018 |
| Photorechargeable High Voltage Redox Battery Enabled by Ta3N5 and GaN/Si Dual‐Photoelectrode Q Cheng, W Fan, Y He, P Ma, S Vanka, S Fan, Z Mi, D Wang Advanced Materials 29 (26), 1700312, 2017 | 76 | 2017 |
| Understanding photocharging effects on bismuth vanadate EY Liu, JE Thorne, Y He, D Wang ACS Applied Materials & Interfaces 9 (27), 22083-22087, 2017 | 57 | 2017 |
| Photo-induced performance enhancement of tantalum nitride for solar water oxidation Y He, P Ma, S Zhu, M Liu, Q Dong, J Espano, X Yao, D Wang Joule 1 (4), 831-842, 2017 | 54 | 2017 |
| Facet-dependent kinetics and energetics of hematite for solar water oxidation reactions W Li, KR Yang, X Yao, Y He, Q Dong, GW Brudvig, VS Batista, D Wang ACS applied materials & interfaces 11 (6), 5616-5622, 2018 | 52 | 2018 |
| Toward practical solar hydrogen production Y He, D Wang Chem 4 (3), 405-408, 2018 | 46 | 2018 |
| Surface chemistry and photoelectrochemistry—Case study on tantalum nitride Y He, R Chen, W Fa, B Zhang, D Wang The Journal of chemical physics 151 (13), 2019 | 24 | 2019 |
| Selectivity of H2O2 and O2 by water oxidation on metal oxide surfaces S Zhu, Y Zhao, Y He, D Wang The Journal of Chemical Physics 150 (4), 2019 | 18 | 2019 |
| Dependence of interface energetics and kinetics on catalyst loading in a photoelectrochemical system Y He, S Vanka, T Gao, D He, J Espano, Y Zhao, Q Dong, C Lang, Y Wang, ... Nano Research 12, 2378-2384, 2019 | 14 | 2019 |
| Photoelectrochemical NADH regeneration is highly sensitive to the nature of electrode surface B Zhang, S Xu, D He, R Chen, Y He, W Fa, G Li, D Wang The Journal of Chemical Physics 153 (6), 2020 | 13 | 2020 |
| In-situ tungsten deposition without barrier layer YH Yong Wu, Wei V. Tang, Jianqiu Guo, Wenyi Liu, Yixiong Yang, Jacqueline S ... US Patent App. 16/835,279, 2020 | | 2020 |
| Solar Fuel Synthesis via Photoelectrochemistry: Understanding and Controlling Interfaces Y He Boston College, 2019 | | 2019 |
| Toward stable Li-O2 battery operations using a water-in-salt electrolyte D Wang, Q Dong, Y Zhao, Y He ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY 256, 2018 | | 2018 |
| 11.1 A Brief History of Nanoscale Photoelectrochemistry JE Thorne, Y He, D Wang Photoelectrochemical Solar Fuel Production: From Basic Principles to …, 2016 | | 2016 |
