| 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 | 105 | 2020 |
| Metastructure with piezoelectric element for simultaneous vibration suppression and energy harvesting G Hu, L Tang, A Banerjee, R Das Journal of Vibration and Acoustics 139 (1), 2017 | 83 | 2017 |
| Analysis and prediction of printable bridge length in fused deposition modelling based on back propagation neural network J Jiang, G Hu*, X Li, X Xu, P Zheng, J Stringer Virtual and Physical Prototyping 14 (3), 253-266, 2019 | 76 | 2019 |
| Acoustic metamaterials with coupled local resonators for broadband vibration suppression G Hu, L Tang, R Das, S Gao, H Liu AIP Advances 7 (2), 025211, 2017 | 73 | 2017 |
| 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 | 70 | 2019 |
| 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 | 67 | 2020 |
| A two-degree-of-freedom piezoelectric energy harvester with stoppers for achieving enhanced performance G Hu, L Tang, R Das, P Marzocca International Journal of Mechanical Sciences 149, 500-507, 2018 | 67 | 2018 |
| Metamaterial beam with graded local resonators for broadband vibration suppression G Hu, ACM Austin, V Sorokin, L Tang Mechanical Systems and Signal Processing 146, 106982, 2021 | 66 | 2021 |
| Effect of support on printed properties in fused deposition modelling processes J Jiang, J Lou, G Hu Virtual and Physical Prototyping 14 (4), 308-315, 2019 | 66 | 2019 |
| Internally coupled metamaterial beam for simultaneous vibration suppression and low frequency energy harvesting G Hu, L Tang, R Das Journal of Applied Physics 123 (5), 055107, 2018 | 64 | 2018 |
| 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 | 57 | 2021 |
| A comb-like beam based piezoelectric system for galloping energy harvesting G Hu, J Wang, L Tang Mechanical Systems and Signal Processing, 2021 | 42 | 2021 |
| Acoustic-elastic metamaterials and phononic crystals for energy harvesting: A review G Hu, L Tang, J Liang, C Lan, R Das Smart Materials and Structures, 2021 | 32 | 2021 |
| Perspectives in flow-induced vibration energy harvesting J Wang, D Yurchenko, G Hu*, L Zhao, L Tang, Y Yang Applied Physics Letters 119 (10), 100502, 2021 | 31 | 2021 |
| Metamaterial with local resonators coupled by negative stiffness springs for enhanced vibration suppression G Hu, L Tang, J Xu, C Lan, R Das Journal of Applied Mechanics 86 (8), 081009, 2019 | 31 | 2019 |
| On the modelling of membrane-coupled Helmholtz resonator and its application in acoustic metamaterial system G Hu, L Tang, X Cui Mechanical Systems and Signal Processing 132, 595-608, 2019 | 28 | 2019 |
| Dynamics and performance of a two degree-of-freedom galloping-based piezoelectric energy harvester C Lan, L Tang, G Hu, W Qin Smart Materials and Structures 28 (4), 045018, 2019 | 24 | 2019 |
| An impact-engaged two-degrees-of-freedom Piezoelectric Energy Harvester for Wideband Operation G Hu, L Tang, R Das Procedia engineering 173, 1463-1470, 2017 | 24 | 2017 |
| Bluff body with built‐in piezoelectric cantilever for flow‐induced energy harvesting M Zhang, G Hu#, J Wang International Journal of Energy Research 44 (5), 3762-3777, 2020 | 22 | 2020 |
| Achieve frequency-self-tracking energy harvesting using a passively adaptive cantilever beam C Lan, Z Chen, G Hu, Y Liao, W Qin Mechanical Systems and Signal Processing 156, 107672, 2021 | 20 | 2021 |
Lihua TANGSenior Lecturer (above bar), The University of AucklandVerified email at auckland.ac.nz
