| Photoelectrochemical water splitting in separate oxygen and hydrogen cells A Landman, H Dotan, GE Shter, M Wullenkord, A Houaijia, A Maljusch, ... Nature materials 16 (6), 646-651, 2017 | 466 | 2017 |
| Decoupled hydrogen and oxygen evolution by a two-step electrochemical–chemical cycle for efficient overall water splitting H Dotan, A Landman, SW Sheehan, KD Malviya, GE Shter, DA Grave, ... Nature Energy 4 (9), 786-795, 2019 | 315 | 2019 |
| Tunable touch sensor and combined sensing platform: toward nanoparticle-based electronic skin M Segev-Bar, A Landman, M Nir-Shapira, G Shuster, H Haick ACS applied materials & interfaces 5 (12), 5531-5541, 2013 | 182 | 2013 |
| Decoupled photoelectrochemical water splitting system for centralized hydrogen production A Landman, R Halabi, P Dias, H Dotan, A Mehlmann, GE Shter, M Halabi, ... Joule 4 (2), 448-471, 2020 | 103 | 2020 |
| High Performance Core/Shell Ni/Ni(OH)2 Electrospun Nanofiber Anodes for Decoupled Water Splitting A Landman, S Hadash, GE Shter, A Ben‐Azaria, H Dotan, A Rothschild, ... Advanced Functional Materials 31 (14), 2008118, 2021 | 37 | 2021 |
| Methods and system for hydrogen production by water electrolysis A Rothschild, G Grader, G Shter, A Landman, H Dotan | 12 | 2016 |
| Carbon-cloth-supported nickel hydroxide anodes for electrochemical–thermally-activated chemical (E-TAC) water splitting N Hayek, A Landman, Y Halpern, I Slobodkin, ES Davydova, A Rothschild Journal of Materials Chemistry A 10 (2), 726-739, 2022 | 8 | 2022 |
| Decoupled hydrogen and oxygen evolution by a two-step electrochemical–chemical cycle for efficient overall water splitting. Nat Energy 4: 786–795 H Dotan, A Landman, SW Sheehan, KD Malviya, GE Shter, DA Gravel, ... | 7 | 2019 |
| New electrolyzer principles: decoupled water splitting A Landman, A Rothschild, GS Grader Electrochemical Power Sources: Fundamentals, Systems, and Applications, 407-454, 2022 | 4 | 2022 |
| Decoupled Water Splitting: From Basic Science to Application A Landman, GS Grader, A Rothschild arXiv preprint arXiv:2007.13345, 2020 | 2 | 2020 |
| System and method for generation of gases G Grader, G Shter, H Dotan, A Rothschild, A Landman US Patent 11,414,766, 2022 | 1 | 2022 |
| Microelectrode and method for producing same G Grader, H Dotan, A Rothschild, A Landman US Patent App. 18/246,599, 2023 | | 2023 |
| Systems and methods for continuous generation of gases G Grader, A Rothschild, H Dotan, A Landman, KAY Asaf, M Moshkovich US Patent App. 18/040,191, 2023 | | 2023 |
| System and method for generation of gases G Grader, G Shter, H Dotan, A Rothschild, A Landman US Patent App. 17/810,975, 2022 | | 2022 |
| Methods and system for hydrogen production by water electrolysis A Rothschild, G Grader, G Shter, A Landman, H Dotan US Patent 11,208,729, 2021 | | 2021 |
| High-Efficiency Hydrogen Production By Decoupled Water Splitting in an Electrochemical-Chemical Cycle A Landman, H Dotan, GS Grader, A Rothschild 2020 Virtual AIChE Annual Meeting, 2020 | | 2020 |
| Two-Cell Photoelectrochemical Water Splitting Prototype Demonstration System A Landman, A Rothschild, GS Grader, R Halabi, GE Shter, H Dotan 2019 AIChE Annual Meeting, 2019 | | 2019 |
| Membrane-Free Water Splitting for Hydrogen Generation A Landman 2018 AIChE Annual Meeting, 2018 | | 2018 |
| Dissemination level: Public Lead beneficiary: HZB Contracted date of delivery: Mar-17 Actual date of delivery: Mar-17 FF Abdi, Y Ma, JW Jang, I Ahmet, R van de Krol, BS HZB, M Mayer, ... | | |
