| Progress in wearable electronics/photonics—Moving toward the era of artificial intelligence and internet of things Q Shi, B Dong, T He, Z Sun, J Zhu, Z Zhang, C Lee InfoMat 2 (6), 1131-1162, 2020 | 408 | 2020 |
| Development trends and perspectives of future sensors and MEMS/NEMS J Zhu, X Liu, Q Shi, T He, Z Sun, X Guo, W Liu, OB Sulaiman, B Dong, ... Micromachines 11 (1), 7, 2019 | 302 | 2019 |
| Deep learning-enabled triboelectric smart socks for IoT-based gait analysis and VR applications Z Zhang, T He, M Zhu, Z Sun, Q Shi, J Zhu, B Dong, MR Yuce, C Lee npj Flexible Electronics 4 (1), 29, 2020 | 255 | 2020 |
| Flexible, stretchable, and transparent planar microsupercapacitors based on 3D porous laser‐induced graphene W Song, J Zhu, B Gan, S Zhao, H Wang, C Li, J Wang Small 14 (1), 1702249, 2018 | 212 | 2018 |
| Progress in TENG technology—A journey from energy harvesting to nanoenergy and nanosystem J Zhu, M Zhu, Q Shi, F Wen, L Liu, B Dong, A Haroun, Y Yang, P Vachon, ... EcoMat 2 (4), e12058, 2020 | 210 | 2020 |
| Silicone-based triboelectric nanogenerator for water wave energy harvesting TX Xiao, T Jiang, JX Zhu, X Liang, L Xu, JJ Shao, CL Zhang, J Wang, ... ACS applied materials & interfaces 10 (4), 3616-3623, 2018 | 109 | 2018 |
| Toward healthcare diagnoses by machine-learning-enabled volatile organic compound identification J Zhu, Z Ren, C Lee ACS nano 15 (1), 894-903, 2020 | 91 | 2020 |
| Machine learning-enabled textile-based graphene gas sensing with energy harvesting-assisted IoT application J Zhu, M Cho, Y Li, T He, J Ahn, J Park, TL Ren, C Lee, I Park Nano Energy 86, 106035, 2021 | 82 | 2021 |
| Biomimetic turbinate-like artificial nose for hydrogen detection based on 3D porous laser-induced graphene J Zhu, M Cho, Y Li, I Cho, JH Suh, DD Orbe, Y Jeong, TL Ren, I Park ACS applied materials & interfaces 11 (27), 24386-24394, 2019 | 78 | 2019 |
| Continuous direct current by charge transportation for next-generation IoT and real-time virtual reality applications J Zhu, H Wang, Z Zhang, Z Ren, Q Shi, W Liu, C Lee Nano Energy 73, 104760, 2020 | 73 | 2020 |
| Electrospinning poly(l-lactic acid) piezoelectric ordered porous nanofibers for strain sensing and energy harvesting J Zhu, L Jia, R Huang Journal of Materials Science: Materials in Electronics 28, 12080-12085, 2017 | 64 | 2017 |
| A hybrid piezoelectric and triboelectric nanogenerator with PVDF nanoparticles and leaf‐shaped microstructure PTFE film for scavenging mechanical energy J Zhu, Y Zhu, X Wang Advanced Materials Interfaces 5 (2), 1700750, 2018 | 60 | 2018 |
| Volatile organic compounds sensing based on Bennet doubler-inspired triboelectric nanogenerator and machine learning-assisted ion mobility analysis J Zhu, Z Sun, J Xu, RD Walczak, JA Dziuban, C Lee Science Bulletin 66 (12), 1176-1185, 2021 | 58 | 2021 |
| Programmed-triboelectric nanogenerators—a multi-switch regulation methodology for energy manipulation H Wang, J Zhu, T He, Z Zhang, C Lee Nano Energy 78, 105241, 2020 | 48 | 2020 |
| Half-pipe palladium nanotube-based hydrogen sensor using a suspended nanofiber scaffold M Cho, J Zhu, H Kim, K Kang, I Park ACS applied materials & interfaces 11 (14), 13343-13349, 2019 | 42 | 2019 |
| A flexible comb electrode triboelectric–electret nanogenerator with separated microfibers for a self-powered position, motion direction and acceleration tracking sensor J Zhu, X Guo, D Meng, M Cho, I Park, R Huang, W Song Journal of Materials Chemistry A 6 (34), 16548-16555, 2018 | 41 | 2018 |
| Machine learning-augmented wearable triboelectric human-machine interface in motion identification and virtual reality J Zhu, S Ji, J Yu, H Shao, H Wen, H Zhang, Z Xia, Z Zhang, C Lee Nano Energy 103, 107766, 2022 | 38 | 2022 |
| Hybrid electromagnetic and triboelectric nanogenerators with multi-impact for wideband frequency energy harvesting J Zhu, A Wang, H Hu, H Zhu Energies 10 (12), 2024, 2017 | 38 | 2017 |
| Zinc oxide-enhanced piezoelectret polypropylene microfiber for mechanical energy harvesting J Zhu, Y Zhu, W Song, H Wang, M Gao, M Cho, I Park ACS applied materials & interfaces 10 (23), 19940-19947, 2018 | 36 | 2018 |
| Enhanced in-vitro osteoblastic functions on β-type titanium alloy using surface mechanical attrition treatment R Huang, L Zhang, L Huang, J Zhu Materials Science and Engineering: C 97, 688-697, 2019 | 30 | 2019 |
