| Self-Powered Rewritable Electrochromic Display based on WO3-x Film with Mechanochemically Synthesized MoO3–y Nanosheets W Wu, H Fang, H Ma, L Wu, Q Wang, H Wang ACS Applied Materials & Interfaces 13 (17), 20326-20335, 2021 | 66 | 2021 |
| Rapidly photocurable solid‐state poly (ionic liquid) ionogels for thermally robust and flexible electrochromic devices WC Poh, ALS Eh, W Wu, X Guo, PS Lee Advanced Materials 34 (51), 2206952, 2022 | 64 | 2022 |
| Boosting Transport Kinetics of Ions and Electrons Simultaneously by Ti3C2Tx (MXene) Addition for Enhanced Electrochromic Performance W Wu, H Fang, H Ma, L Wu, W Zhang, H Wang Nano-Micro Letters 13, 1-13, 2021 | 57 | 2021 |
| Self‐powered and light‐adaptable stretchable electrochromic display W Wu, WC Poh, J Lv, S Chen, D Gao, F Yu, H Wang, H Fang, H Wang, ... Advanced Energy Materials 13 (18), 2204103, 2023 | 46 | 2023 |
| A high-performance transparent photodetector via building hierarchical g-C3N4 nanosheets/CNTs van der Waals heterojunctions by a facile and scalable approach H Fang, H Ma, C Zheng, S Lennon, W Wu, L Wu, H Wang Applied Surface Science 529, 147122, 2020 | 39 | 2020 |
| Self-doped tungsten oxide films induced by in situ carbothermal reduction for high performance electrochromic devices L Zhou, P Wei, H Fang, W Wu, L Wu, H Wang Journal of Materials Chemistry C 8 (40), 13999-14006, 2020 | 37 | 2020 |
| Electrochromic Devices Constructed with Water-in-Salt Electrolyte Enabling Energy-saving and Prolonged Optical Memory Effect W Wu, L Wu, H Ma, L Wu, H Wang, H Fang Chemical Engineering Journal 446, 137122, 2022 | 32 | 2022 |
| A self-powered photoelectrochemical ultraviolet photodetector based on Ti3C2T x/TiO2 in situ formed heterojunctions H Ma, L Jia, Y Lin, H Fang, W Wu, L Wu, B Hu, H Wang Nanotechnology 33 (7), 075502, 2021 | 28 | 2021 |
| A highly transparent humidity sensor with fast response speed based on α-MoO 3 thin films H Ma, H Fang, W Wu, C Zheng, L Wu, H Wang RSC advances 10 (43), 25467-25474, 2020 | 22 | 2020 |
| Progress in flexible electrochromic devices F Huajing, Z Zetian, W Wenting, W Hong Journal of Inorganic Materials 36 (2), 140-151, 2021 | 17 | 2021 |
| A highly stretchable, self-healable, transparent and solid-state poly (ionic liquid) filler for high-performance dielectric elastomer actuators H Wang, MWM Tan, WC Poh, D Gao, W Wu, PS Lee Journal of Materials Chemistry A 11 (26), 14159-14168, 2023 | 13 | 2023 |
| Dual-function biomimetic eyes based on thermally-stable organohydrogel electrolyte H Fang, L Wu, H Ma, W Wu, L Wu, Y Zhang, H Wang Chemical Engineering Journal 438, 135383, 2022 | 8 | 2022 |
| Temperature-dependent electrochromic devices for energy-saving dual-mode displays W Wu, H Fang, L Wu, H Ma, H Wang ACS Applied Materials & Interfaces 15 (3), 4113-4121, 2023 | 7 | 2023 |
| Monolithic integrated multifunctional photoelectrochemical device for smart ultraviolet management L Wu, H Fang, W Wu, H Ma, C Zheng, H Wang Materials Today Energy 20, 100676, 2021 | 7 | 2021 |
| Flexible and stretchable electrochromic displays: strategies, recent advances, and prospects W Wu, PS Lee Soft Science 4 (3), N/A-N/A, 2024 | 3 | 2024 |
| 3D‐Printed Electrohydrodynamic Pump and Development of Anti‐Swelling Organohydrogel for Soft Robotics Y Xin, X Zhou, MRJ Tan, S Chen, P Huang, Y Jiang, W Wu, D Gao, J Lv, ... Advanced Materials, 2415210, 2025 | | 2025 |
| Self‐Powered and Light‐Adaptable Stretchable Electrochromic Display (Adv. Energy Mater. 18/2023) W Wu, WC Poh, J Lv, S Chen, D Gao, F Yu, H Wang, H Fang, H Wang, ... Advanced Energy Materials 13 (18), 2370071, 2023 | | 2023 |
Hong WangSouthern University of Science and Technology, Xi'an Jiaotong UniversityПідтверджена електронна адреса в sustech.edu.cn