代表性论文专著
期刊论文
【2022】
[57] L Zhang, T Tan, Z Yue, Z Yan. Topological imbalanced phononic crystal with semi-enclosed defect for high-performance acoustic energy confinement and harvesting. Nano Energy, 2022, 100: 107472.
https://authors.elsevier.com/c/1fDks_oHs0pRbc
[56] X Nie, S Pei, T Tan, Z Yan, Z Yan. Nonlinear 1:2 internal resonance response of L-shaped piezoelectric energy harvester under the influence of electrical damping. International Journal of Mechanical Science, 2022, 225: 107365.
[55] C Huang, T Tan, Z Wang, S Zhang, F Yang, Z Lin, Z Yan. Origami dynamics based soft piezoelectric energy harvester for machine learning assisted self-powered gait biometric identification. Energy Conversion and Management, 2022, 263: 115720.
[54] Z. Wang, Y. Du, T. Li, Z. Yan, T. Tan*. Bioinspired omnidirectional piezoelectric energy harvester with autonomous direction regulation by hovering vibrational stabilization. Energy Conversion and Management, 2022, 261: 115638.
[53] Z. Yan, H. Xiao, Y. Liu, T Tan*. Band-gap dynamics and programming for low-frequency broadband acoustic metamaterial. Composite Structures, 2022, 14: 115535.
https://doi.org/10.1016/j.compstruct.2022.115535
[52] G. Shi, T. Tan, S. Hu, Z. Yan. Hydrodynamic piezoelectric energy harvesting with topological strong vortex by forced separation. International Journal of Mechanical Science, 2022, 223: 107261.
[51] X. Nie, X. Can, L. Wang, T. Tan, Z-T Yan, Z. Yan, X. Liu. Nonlinear analysis of the internal resonance response of an L-shaped beam structure considering quadratic and cubic nonlinearity. Journal of Statistical Mechanics-Theory and Experiment, 2022, Accepted
[50] K. Sun, X. Nie, T. Tan, Z. Yu, Z. Yan. Coupled vortex-induced modeling for spatially large-curved beam with elastic support. International Journal of Mechanical Science, 214 (2022) 106903.
【2021】
[49] Z. Yan, G. Shi, J. Zhou, L. Wang, L. Zuo, T. Tan*. Wind piezoelectric energy harvesting enhanced by elastic-interfered wake-induced vibration. Energy Conversion & Management, 249 (2021) 114820.
[48] Tianrun Li, Zhemin Wang, Hanjie Xiao, Zhimiao Yan, Cheng Yang, Ting Tan*. Dual-band piezoelectric acoustic energy harvesting by structural and local resonances of Helmholtz metamaterial. Nano Energy, 90 (2021) 106523.
[47] Donglin Zou, Gaoyu Liu, Zhushi Rao, Ting Tan, Wenming Zhang, Wei-Hsin Liao*. Design of a Multi-stable Piezoelectric Energy Harvester with Programmable Equilibrium Point Configurations. Applied Energy, 302 (2021) 117585.
[46] Zhemin Wang, Tianrun Li, Yu Du, Zhimiao Yan, Ting Tan*. Nonlinear broadband piezoelectric vibration energy harvesting enhanced by inter-well modulation. Energy Conversion & Management, 2021, 246 (2021) 114661.
[45] Zhemin Wang, Yu Du, Tianrun Li, Zhimiao Yan, Ting Tan*. A flute-inspired broadband piezoelectric vibration energy harvesting device with mechanical intelligent design. Applied Energy, 303 (2021) 117577.
[44] Ting Tan, Zhemin Wang, Liang Zhang, Wei-Hsin Liao, Zhimiao Yan. Piezoelectric autoparametric vibration energy harvesting with chaos control feature. Mechanical Systems and Signal Processing, 2021, 161: 107989.
[43] Ting Tan, Lei Zuo, Zhimiao Yan. Environment coupled piezoelectric galloping wind energy harvesting. Sensors and Actuators A, 323 (2021) 112641
[42] Daoli Zhao, Jie Zhou, Ting Tan, Zhimiao Yan, Weipeng Sun, Junlian Yin, Wenming Zhang. Hydrokinetic piezoelectric energy harvesting by wake induced vibration. Energy 220 (2021) 119722
[41] Kejing Ma, Ting Tan*, Zhimiao Yan, Fengrui Liu, Wei-Hsin Liao, Wenming Zhang*
Metamaterial and Helmholtz coupled resonator for high-density acoustic energy harvesting
Nano Energy 82 (2021) 105693.
[40] Donglin Zou; Gaoyu Liu; Zhushi Rao; Ting Tan; Wenming Zhang; Wei-Hsin Liao*.
Design of Vibration Energy Harvesters with Customized Nonlinear Forces
Mechanical Systems and Signal Processing, 2021, 153: 107526
[39] Donglin Zou, Gaoyu Liu; Zhushi Rao, Ting Tan, Wenming Zhang, Wei-Hsin Liao*.
A device capable of customizing nonlinear forces for vibration energy harvesting, vibration isolation, and nonlinear energy sink.
Mechanical Systems and Signal Processing, 2021, 147: 107101.
【2020】
[38] Daoli Zhao, Xinyu Hu, Ting Tan, Zhimiao Yan, Wenming Zhang. Piezoelectric galloping energy harvesting enhanced by topological equivalent aerodynamic design, Energy Conversion and Management, 2020, 222: 113260.
[37]Ke-Jing Ma, Ting Tan*, Feng-Rui Liu, Lin-Chuan Zhao, Wei-Hsin Liao, Wen-Ming Zhang.
Acoustic energy harvesting enhanced by locally resonant metamaterials
Smart Materials and Structures, 29 (2020) 075025.
Full-text Link: https://doi.org/10.1088/1361-665X/ab8fcc
[36]Xiaochun Nie, Ting Tan, Zhimiao Yan, Zhitao Yan, Wenming Zhang.
An ultra wide-band piezoelectric energy harvester based on Stockbridge damper and its application in transmission lines for smart grid.
Applied Energy 2020, 267, 114898.
[35]Ge Yan; Hong-Xiang Zou; Sen Wang; Lin-Chuan Zhao; Qiu-Hua Gao; Ting Tan; Wen-Ming Zhang*.
Large stroke quasi-zero stiffness vibration isolator using three-link mechanism.
Journal of Sound and Vibration, 2020, 478: 115344.
[34]Ting Tan, Zhimiao Yan, Kejing Ma, Fengrui Liu, Linchuan Zhao, Wenming Zhang*.
Nonlinear characterization and performance optimization for broadband bistable energy harvester.
Acta Mechanica Sinica, 2020, 36: 578–591.
[33]Zhimiao Yan, Weipeng Sun, Muhammad R Hajj, Wenming Zhang, Ting Tan*.
Ultra-broadband piezoelectric energy harvesting via bistable multi-hardening and multi-softening.
Nonlinear Dynamics, (2020) 100:1057–1077
[32]Yan G, Zou HX, Yan H, Tan T, Wang S, Zhang WM*, Peng ZK, Meng G.
Multi-Direction Vibration Isolator for Momentum Wheel Assemblies.
ASME Journal of Vibration and Acoustics, 2020, 142(4): 041007.
[31] Zhimiao Yan, Lingzhi Wang, Muhammad R. Hajj, ZhitaoYan, Yi Sun, Ting Tan*.
Energy harvesting from iced-conductor inspired wake galloping.
Extreme Mechanics Letters, 35 (2020) 100633
Full-text Link: https://doi.org/10.1016/j.eml.2020.100633
[30] Ting Tan, Xinyu Hu, Zhimiao Yan, Yajian Zou, Wenming Zhang.
Piezoelectromagnetic synergy design and performance analysis forwind galloping energy harvester.
Sensors and Actuators A, 302 (2020) 111813.
Full-text Link: https://doi.org/10.1016/j.sna.2019.111813
[29] Feng-Rui Liu, Wen-Ming Zhang*, Lin-Chuan Zhao, Hong-Xiang Zou, Ting Tan, Zhi-Ke Peng, Guang Meng.
Performance enhancement of wind energy harvester utilizing wake flow induced by double upstream flat-plates.
Applied Energy, 2020, 257: 114034.
2019
[28] Zhao, L. C., Zou, H. X., Gao, Q. H., Yan, G., Liu, F. R., Tan, T., ... & Zhang, W. M*. (2019). Magnetically modulated orbit for human motion energy harvesting. Applied Physics Letters, 115(26), 263902.
[27] Lin-Chuan Zhao, Hong-Xiang Zou, Ge Yan, Feng-Rui Liu, Ting Tan, Ke-Xiang Wei, Wen-Ming Zhang*. Magnetic coupling and flextensional amplification mechanisms for high-robustness ambient wind energy harvesting. Energy Conversion and Management, 2019, 201: 112166.
[26] Hong-Xiang Zou, Lin-Chuan Zhao, Lei Zuo, Feng-Rui Liu, Ting Tan, Ke-Xiang Wei, Wen-Ming Zhang*. Mechanical modulations for enhancing energy harvesting: principles, methods and applications. Applied Energy, 2019, 255: 113871.
[25] Ting Tan, Xinyu Hu, Zhimiao Yan, Wenming Zhang. Enhanced low-velocity wind energy harvesting from transverse galloping with super capacitor. Energy, 2019, 187: 115915.
[24] Ting Tan, Zhimiao Yan, Hongxiang Zou, Kejing Ma, Fengrui Liu, Linchuan Zhao, Zhike Peng, Wenming Zhang*. Renewable energy harvesting and absorbing via multi-scale metamaterial systems for Internet of things. Applied Energy, 2019, 254: 113717.
[23] Lingzhi Wang, Ting Tan, Zhimiao Yan, Dezhi Li, Bin Zhang, Zhitao Yan. Integration of tapered beam and four direct-current circuits for enhanced energy harvesting from transverse galloping. IEEE/ASME Transactions on Mechatronics, 2019, 24(5): 2248-2260.
[22] Lingzhi Wang, Ting Tan, Zhimiao Yan, Zhitao Yan. Tapered galloping energy harvester for power enhancement and vibration reduction. Journal of Intelligent Material Systems and Structures, 2019, 30(18-19): 2853-2869.
[21] Xiaochuan Nie, Ting Tan, Zhimiao Yan, Zhitao Yan, Muhammad R Hajj. Broadband and high-efficient L-shaped energy harvester based on internal resonance. International Journal of Mechanical Science, 2019, 159: 287-305.
[20] Weipeng Sun, Daoli Zhao, Ting Tan, Zhimiao Yan, Pengcheng Guo, Xingqi Luo. Low velocity water flow energy harvesting using vortex induced vibration and galloping. Applied Energy, 2019, 251: 113392
[19] Lin-Chuan Zhao, Hong-Xiang Zou, Ge Yan, Feng-Rui Liu, Ting Tan, Wen-Ming Zhang*, Zhi-Ke Peng and Guang Meng. A water-proof magnetically coupled piezoelectric-electromagnetic hybrid wind energy harvester. Applied Energy, 2019, 239: 735–746.
[18] Ting Tan, Zhimiao Yan, Yajian Zou, Wenming Zhang, Optimal dual-functional design for a piezoelectric autoparametric vibration absorber, Mechanical Systems and Signal Processing, 2019,123: 513-532.
2018
[17] Zhimiao Yan, Hong Lei, Ting Tan, Weipeng Sun, Wenhu Huang, Nonlinear analysis for dual-frequency concurrent energy harvesting, Mechanical Systems and Signal Processing, 2018,104: 514-535
[16] Weipeng Sun, Zhimiao Yan, Ting Tan, Daoli Zhao and Xingqi Luo, Nonlinear characterization of the rotor-bearing system with oil-film and unbalance forces considering the oil-temperature effect. Nonlinear Dynamics, 2018, 92(3): 1119–1145
[15] Zhimiao Yan, Weipeng Sun, Ting Tan and Wenhu Huang, Nonlinear analysis of galloping piezoelectric energy harvesters with inductive-resistive circuits for boundaries of analytical solutions, Communications in Nonlinear Science and Numerical Simulation, 2018, 62: 90-116
[14] Sun, W., Tan, T., Yan, Z., Zhao, D., Luo, X., & Huang, W. Energy harvesting from water flow in open channel with macro fiber composite. AIP Advances, 2018, 8(9), 095107.
2017
[13] Ting Tan, Zhimiao Yan, Wenhu Huang, Broadband design of hybrid piezoelectric energy harvester, International Journal of Mechanical Sciences, 2017, 131-132: 516-526
https://www.sciencedirect.com/science/article/pii/S0020740317313267
[12] Ting Tan, Zhimiao Yan. Electromechanical decoupled model for cantilever-beam piezoelectric energy harvesters with inductive-resistive circuits and its application in galloping mode. Smart Materials and Structures, 2017, 26: 035062.
[11] Ting Tan, Zhimiao Yan, Hong Lei, Optimization and performance comparison for galloping-based piezoelectric energy harvesters with alternating-current and direct-current interface circuits, Smart Materials and Structures, 2017, 26: 075007
[10] Ting Tan, Zhimiao Yan, Hong Lei, Weipeng Sun, Geometric nonlinear distributed parameter model for cantilever-beam piezoelectric energy harvesters and structural dimension analysis for galloping mode, Journal of Intelligent Material Systems and Structures, 2017, 28(20): 3066-3078.
[9] Ting Tan, Zhimiao Yan, Optimization study on inductive-resistive circuit for broadband piezoelectric energy harvesters, AIP advances, 2017, 7: 035318
[8] Zhimiao Yan, Haithem E. Taha, Ting Tan, Nonlinear characteristics of an autoparametric vibration system, Journal of Sound and Vibration, 2017, 390(3): 1-22
2016
[7] Ting Tan, Zhimiao Yan, Muhammad R. Hajj. Electromechanical decoupled model for cantilever-beam piezoelectric energy harvesters, Applied Physics Letters, 2016, 109(25): 101908.
[6] Ting Tan, Zhimiao Yan. Analytical solution and optimal design for galloping-based piezoelectric energy harvesters. Applied Physics Letters, 2016, 109(25): 253902.
[5] Ting Tan, Nathan M. Cholewa, Scott W Case, Raffaella De Vita. Micro-structural and biaxial creep properties of the swine uterosacral–cardinal ligament complex. Annals of Biomedical Engineering, 2016, 44: 3225.
[4] Adwoa Baah-Dwomoh, Jeffrey McGuire, Ting Tan, Raffaella De Vita, Mechanical properties of female reproductive organs and supporting connective tissues: a review of the current state of knowledge, Applied Mechanics Reviews, 2016, 68: 060801
2015
[3] Ting Tan, Frances Davis, Jason Massengill, Daniel Gruber, John Robertson and Raffaella De Vita, Histo-mechanical properties of swine uterosacral and cardinal ligaments. Journal of the Mechanical Behavior of Biomedical Materials, 2015, 42: 129-137.
[2] Ting Tan, Raffaella De Vita, A structural constitutive model for smooth muscle contraction in biological tissues. International Journal of Non-Linear Mechanics, 2015, 75: 46-53.
2012
[1] Zhimiao Yan, Zhitao Yan, Zhengliang Li, Ting Tan, Nonlinear galloping of internally resonant iced transmission lines considering eccentricity, Journal of Sound and Vibration, 2012, 331: 3599-3616.
学术会议
• 受邀国际会议报告 (Invited Talk)
(1) Ting Tan, Zhimiao Yan, Wenhu Huang. Theoretical and Experimental Study on Piezoelectric Energy Harvesting for Vibration Control and Sensor Powering. European Advanced Materials Congress, Stockholm, Sweden, 2018.08.20-08.23
(2) Ting Tan, Zhimiao Yan, Wenhu Huang. Optimal design for galloping piezoelectric energy harvesters, Collaborative Conference on Materials Research (CCMR) 2017 meeting, Jeju island, South Korea, 2017.06.26-06.30
(3) Ting Tan and Raffaella De Vita, A Structural Constitutive Model for Smooth Muscle Contraction: Application to Arteries, World Congress of Biomechanics, Dublin, Ireland, 2018.07.08-07.12
• 国内外会议报告 (Oral Presentation)
(1) Ting Tan, zhimiao Yan, Lingzhi Wang, Wenhu Huang. Performance of tapered piezoelectric energy harvesting from galloping, Advanced Materials World Congress 2018, Singapore, 2018.2.5-2.8
(2) Ting Tan, Zhimiao Yan, Weipeng Sun, Wenhu Huang. Performance comparative study on piezoelectric energy harvesters under base and galloping excitations through equivalent power, 17th Asian Pacific Vibration Conference, Nanjing, China, 2017.11.13-11.15
(3) Ting Tan, Zhimiao Yan, Wenhu Huang. Dual-functional design for a piezoelectric autoparametric absorber, 2017年全国压电和声波理论及器件应用研讨会,中国,成都,2017年10月27-30日
(4) Ting Tan, Zhimiao Yan, Wenhu Huang. Electromechanical decoupled model for piezoelectric energy harvesters, 中国力学大会 2017,中国,北京,2017年8月13-16日
(5) Ting Tan, Zhimiao Yan, Wenhu Huang. Optimal design for galloping piezoelectric energy harvesters based on analytical solution, 第十六届全国非线性振动暨第十三届全国非线性动力学和运动稳定性学术会议,中国,杭州,2017年5月25-27日
(6) Ting Tan, Zhimiao Yan, Yushu Chen, Electromechanical modeling and analysis for cantilever-beam piezoelectric energy harvesters, 第十届全国动力学与控制学术会议,中国,成都,2016年5月6-8日
(7) Ting Tan, Nathan Cholewa, Scott Case, Raffaella De Vita*. Micro-structural and biaxial creep properties of the swine uterosacral-cardinal ligament complex. Society of Engineering Science 52nd Annual Technical Meeting, 2015, College Station, U.S.A., 2015.10.26-10.28
(8) Ting Tan, Frances Davis, Suzanne Nicewonder, Raffaella De Vita. Elastic properties of uterosacral and cardinal ligaments from uniaxial tensile tests. 91st Annual Meeting Virginia Academy of Science, 2013, Blacksburg, U.S.A., 2013.05.22-05.24
(9) Winston Becker, Ting Tan, and Raffaella De Vita. Biaxial mechanical properties of utero-sacral and cardinal ligaments, 11th World Congress on Computational Mechanics (WCCM XI), 5th European Conference on Computational Mechanics (ECCM V), 6th European Conference on Computational Fluid Dynamics (ECFD VI), 2014, Barcelona, Spain, 2014.07.20-07.25
(10) Winston Becker, Ting Tan, and Raffaella De Vita. Biaxial viscoelasticity of uterosacral and cardinal ligaments, 7th World Congress of Biomechanics, 2014, Boston, U.S.A., 2014.07.06-07.11
(11) Frances Davis, Ting Tan, Suzanne Nicewonder, Raffaella De Vita. Tensile properties of the swine cardinal ligament, ASME Proceedings, Reproductive Tissue Mechanics, 2013, Paper No. SBC2013-14294, pp. V01BT52A002, doi:10.1115/SBC2013-14294.
• 国际会议海报 (Poster Presentation)
(1) Ting Tan, Nathan Cholewa, Scott Case, Raffaella De Vita. Creep properties of swine uterosacral and cardinal ligaments, Biomedical Engineering Society (BMES) Annual Meeting, 2015, Tampa, U.S.A, 2015.10.07-10.10
(2) Ting Tan, Raffaella De Vita. Biaxial creep of swine cardinal and uterosacral ligaments. Summer Biomechanics, Bioengineering and Biotransport Conference (SB3C), 2015, Snowbird, U.S.A., 2015.06.17-06.20
(3) Ting Tan, Raffaella De Vita. A structural constitutive model for the active and passive behavior of biological tissues. Summer Biomechanics, Bioengineering and Biotransport Conference (SB3C), 2015, Snowbird, U.S.A., 2015.06.17-06.20
(4) Ting Tan, Raffaella De Vita. Structural constitutive model for smooth muscle contraction. Biomedical Engineering Society (BMES) Annual Meeting, 2014, San Antonio, U.S.A, 2014.10.22-10.25
(5) Ting Tan, Frances Davis, Suzanne Nicewonder, Jason Massengill, Daniel Gruber, and Raffaella De Vita. Location-dependent tensile properties of the swine uterosacral-cardinal ligament complex. Biomedical Engineering Society (BMES) Annual Meeting, 2013, Seattle, U.S.A., 2013.09.25-09.28
(6) Adwoa Baah-Dwomoh, Ting Tan, Raffaella De Vita, Nonlinear viscoelasticity of ligaments of the pelvic floor, Biomedical Engineering Society (BMES) Annual Meeting, 2015, Tampa, U.S.A, 2015.10.7-10.10