| The state-of-the-art review on energy harvesting from flow-induced vibrations J Wang, L Geng, L Ding, H Zhu, D Yurchenko Applied Energy 267, 114902, 2020 | 548 | 2020 |
| High-performance piezoelectric wind energy harvester with Y-shaped attachments J Wang, S Zhou, Z Zhang, D Yurchenko Energy conversion and management 181, 645-652, 2019 | 488 | 2019 |
| Efficiency investigation on energy harvesting from airflows in HVAC system based on galloping of isosceles triangle sectioned bluff bodies J Wang, L Tang, L Zhao, Z Zhang Energy 172, 1066-1078, 2019 | 231 | 2019 |
| Hybrid wind energy scavenging by coupling vortex-induced vibrations and galloping J Wang, S Gu, C Zhang, G Hu, G Chen, K Yang, H Li, Y Lai, G Litak, ... Energy Conversion and Management 213, 112835, 2020 | 222 | 2020 |
| A double-beam piezo-magneto-elastic wind energy harvester for improving the galloping-based energy harvesting K Yang, J Wang, D Yurchenko Applied Physics Letters 115 (19), 2019 | 219 | 2019 |
| Effectiveness of amino acid salt solutions in capturing CO2: A review Z Zhang, Y Li, W Zhang, J Wang, MR Soltanian, AG Olabi Renewable and Sustainable Energy Reviews 98, 179-188, 2018 | 202 | 2018 |
| A hybrid piezo-dielectric wind energy harvester for high-performance vortex-induced vibration energy harvesting Z Lai, S Wang, L Zhu, G Zhang, J Wang, K Yang, D Yurchenko Mechanical Systems and Signal Processing 150, 107212, 2021 | 168 | 2021 |
| Design, modeling and experiments of broadband tristable galloping piezoelectric energy harvester J Wang, L Geng, S Zhou, Z Zhang, Z Lai, D Yurchenko Acta Mechanica Sinica 36, 592-605, 2020 | 157 | 2020 |
| Flow-induced vibration of a circular cylinder with splitter plates placed upstream and downstream individually and simultaneously H Zhu, G Li, J Wang Applied Ocean Research 97, 102084, 2020 | 146 | 2020 |
| On the use of metasurface for Vortex-Induced vibration suppression or energy harvesting J Wang, S Sun, L Tang, G Hu, J Liang Energy conversion and management 235, 113991, 2021 | 138 | 2021 |
| Performance evaluation of twin piezoelectric wind energy harvesters under mutual interference G Hu, J Wang, Z Su, G Li, H Peng, KCS Kwok Applied Physics Letters 115 (7), 2019 | 134 | 2019 |
| Dual serial vortex-induced energy harvesting system for enhanced energy harvesting S Zhou, J Wang AIP Advances 8 (7), 2018 | 128 | 2018 |
| A comb-like beam based piezoelectric system for galloping energy harvesting G Hu, J Wang, L Tang Mechanical Systems and Signal Processing 150, 107301, 2021 | 107 | 2021 |
| Harvest wind energy from a vibro-impact DEG embedded into a bluff body ZH Lai, JL Wang, CL Zhang, GQ Zhang, D Yurchenko Energy Conversion and Management 199, 111993, 2019 | 101 | 2019 |
| A cross-coupled dual-beam for multi-directional energy harvesting from vortex induced vibrations J Wang, G Hu, Z Su, G Li, W Zhao, L Tang, L Zhao Smart Materials and Structures 28 (12), 12LT02, 2019 | 99 | 2019 |
| Two-degree-of-freedom flow-induced vibration of a rotating circular cylinder Q Zou, L Ding, H Wang, J Wang, L Zhang Ocean Engineering 191, 106505, 2019 | 97 | 2019 |
| Perspectives in flow-induced vibration energy harvesting J Wang, D Yurchenko, G Hu, L Zhao, L Tang, Y Yang Applied Physics Letters 119 (10), 2021 | 92 | 2021 |
| Equivalent circuit representation of a vortex‐induced vibration‐based energy harvester using a semi‐empirical lumped parameter approach J Wang, L Tang, L Zhao, G Hu, R Song, K Xu International journal of energy research 44 (6), 4516-4528, 2020 | 91 | 2020 |
| Enhancement of low-speed piezoelectric wind energy harvesting by bluff body shapes: Spindle-like and butterfly-like cross-sections J Wang, C Zhang, S Gu, K Yang, H Li, Y Lai, D Yurchenko Aerospace Science and Technology 103, 105898, 2020 | 90 | 2020 |
| Offshore renewable energy site correlated wind-wave statistics O Gaidai, F Wang, Y Wu, Y Xing, AR Medina, J Wang Probabilistic Engineering Mechanics 68, 103207, 2022 | 80 | 2022 |
Daniil Yurchenko (Iourtchenko)University of SouthamptonDirección de correo verificada de soton.ac.uk