Energy harvesting during human walking to power a wireless sensor node Y Kuang, T Ruan, ZJ Chew, M Zhu Sensors and Actuators A: Physical 254, 69-77, 2017 | 121 | 2017 |
Design and characterisation of a piezoelectric knee-joint energy harvester with frequency up-conversion through magnetic plucking Y Kuang, Z Yang, M Zhu Smart Materials and Structures 25 (8), 085029, 2016 | 116 | 2016 |
Auxetic piezoelectric energy harvesters for increased electric power output Q Li, Y Kuang, M Zhu Aip Advances 7 (1), 2017 | 110 | 2017 |
Resonance tracking and vibration stablilization for high power ultrasonic transducers Y Kuang, Y Jin, S Cochran, Z Huang Ultrasonics 54 (1), 187-194, 2014 | 106 | 2014 |
Auxetic structure for increased power output of strain vibration energy harvester WJG Ferguson, Y Kuang, KE Evans, CW Smith, M Zhu Sensors and Actuators A: Physical 282, 90-96, 2018 | 91 | 2018 |
Characterisation of a knee-joint energy harvester powering a wireless communication sensing node Y Kuang, M Zhu Smart Materials and Structures 25 (5), 055013, 2016 | 75 | 2016 |
Design study of a mechanically plucked piezoelectric energy harvester using validated finite element modelling Y Kuang, M Zhu Sensors and Actuators A: Physical 263, 510-520, 2017 | 72 | 2017 |
A sandwiched piezoelectric transducer with flex end-caps for energy harvesting in large force environments Y Kuang, A Daniels, M Zhu Journal of Physics D: Applied Physics 50 (34), 345501, 2017 | 59 | 2017 |
High-performance planar ultrasonic tool based on d31-mode piezocrystal MR Sadiq, Y Kuang, S Cochran, Z Huang IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control 62 …, 2015 | 59 | 2015 |
Evaluation and validation of equivalent properties of macro fibre composites for piezoelectric transducer modelling Y Kuang, M Zhu Composites Part B: Engineering 158, 189-197, 2019 | 47 | 2019 |
Scalable pendulum energy harvester for unmanned surface vehicles J Graves, Y Kuang, M Zhu Sensors and Actuators A: Physical 315, 112356, 2020 | 40 | 2020 |
Kirigami-inspired triboelectric nanogenerator as ultra-wide-band vibrational energy harvester and self-powered acceleration sensor Y Qi, Y Kuang, Y Liu, G Liu, J Zeng, J Zhao, L Wang, M Zhu, C Zhang Applied Energy 327, 120092, 2022 | 37 | 2022 |
Counterweight-pendulum energy harvester with reduced resonance frequency for unmanned surface vehicles J Graves, Y Kuang, M Zhu Sensors and Actuators A: Physical 321, 112577, 2021 | 36 | 2021 |
Strongly coupled piezoelectric energy harvesters: Finite element modelling and experimental validation Y Kuang, ZJ Chew, M Zhu Energy conversion and management 213, 112855, 2020 | 32 | 2020 |
Roadmap on nanogenerators and piezotronics P Basset, SP Beeby, C Bowen, ZJ Chew, A Delbani, RD Dharmasena, ... APL materials 10 (10), 2022 | 31 | 2022 |
Frequency band broadening and charge density enhancement of a vibrational triboelectric nanogenerator with two stoppers Y Qi, G Liu, Y Kuang, L Wang, J Zeng, Y Lin, H Zhou, M Zhu, C Zhang Nano Energy 99, 107427, 2022 | 31 | 2022 |
Strongly coupled piezoelectric energy harvesters: Optimised design with over 100 mW power, high durability and robustness for self-powered condition monitoring Y Kuang, ZJ Chew, J Dunville, J Sibson, M Zhu Energy Conversion and Management 237, 114129, 2021 | 31 | 2021 |
Broadband energy harvesting by nonlinear magnetic rolling pendulum with subharmonic resonance Y Kuang, R Hide, M Zhu Applied energy 255, 113822, 2019 | 31 | 2019 |
Magnetic field energy harvesting from the traction return current in rail tracks Y Kuang, ZJ Chew, T Ruan, T Lane, B Allen, B Nayar, M Zhu Applied Energy 292, 116911, 2021 | 29 | 2021 |
Parametrically excited nonlinear magnetic rolling pendulum for broadband energy harvesting Y Kuang, M Zhu Applied Physics Letters 114 (20), 2019 | 28 | 2019 |