代表作20篇。热弹性阻尼SCI论文10篇: [1] Yuming Fang(方玉明), Pu Li*(李普), Hongyue Zhou, WanliZuo, Thermoelastic damping in flexural vibration of bilayered microbeams withcircular cross-section, AppliedMathematical Modelling77 (2020)1129–1147. [2] Hongyue Zhou(周宏月), Pu Li*(李普), Yuming Fang(方玉明), Thermoelastic Dampingfor rectangular cross-sectional micro- and nano-ring resonators, International Journal of MechanicalSciences 163 (2019) 105132. [3] PuLi*(李普),Yuming Fang(方玉明), Jianrun Zhang,Thermoelastic damping in microrings with circular cross-section, Journal of Sound and Vibration 361(2016) 341-354. [4] Pu Li*(李普), Yuming Fang(方玉明), RufuHu,Thermoelastic damping inrectangular and circular microplate resonators, Journal of sound and vibration 331 (2012) 721-733. [5]Pu Li*(李普),Rufu Hu, Thermoelastic damping in micromechanical resonators with a proof massand a network of suspension beams, JapaneseJournal of applied physics 50 (2011) 077202. [6] Wanli Zuo(左万里), Pu Li*(李普), Yuming Fang(方玉明), Jianrun Zhang, Thermoelastic dampingin asymmetric three-layered microbeam resonators, TRANSACTIONS OF THE ASMEJournal of Applied Mechanics, June 2016, 83(6), 061002. [7] Wanli Zuo(左万里), Pu Li*(李普), Yuming Fang(方玉明), JianrunZhang, Analytical modeling ofthermoelastic damping in bilayered microplate resonators, International Journal of Mechanical Sciences 106 (2016) 128-137. [8] Yongpeng Tai(台永鹏), Pu Li*(李普), Yuming Fang(方玉明), Thermoelastic damping in torsion microresonatorswith coupling effect between torsion and bending, Journal of Sound and Vibration 333 (2014) 1509-1525. [9] Yongpeng Tai(台永鹏), Pu Li*(李普), An analytical model for thermoelastic damping in microresonators basedon entropy generation, TRANSACTIONS OF THE ASME Journal of Vibration and Acoustics, JUNE 2014, Vol. 136, 031012. [10] Wanli Zuo*(左万里), Pu Li(李普), Jianke Du, JiahanHuang, Thermoelastic damping in trilayered microplate resonators, International Journal of MechanicalSciences 151 (2019) 595-608. |
气体气体阻尼SCI论文10篇: [1] Cunhao Lu(陆存豪), Pu Li*(李普), Yuming Fang(方玉明), Analytical model of squeeze filmair damping of perforated plates in the free molecular regime, Microsystem Technologies (2019)25:1753-1761. [2] Cunhao Lu(陆存豪), Pu Li*(李普), Minhang Bao, Yuming Fang(方玉明), A generalized energy transfer modelfor squeeze-film air damping in the free molecular regime, Journal of Micromechanics and Microengineering,28(2018) 085003. [3]Yuming Fang(方玉明), Pu Li*(李普), Fan Yang, Wanli Zuo, Squeeze-film damping of circularmicroplates vibrating in a tilting motion, Microfluidicsand Nanofluidics (2016) 20:152. [4] PuLi*(李普), Yuming Fang(方玉明), Haiqiang Wu, A numericalmolecular dynamics approach for squeeze-film damping of perforated MEMSstructures in the free molecular regime, Microfluidics and Nanofluidics, (2014)17:759-772. [5] Pu Li*(李普), Yuming Fang(方玉明), Feifei Xu, Analytical modeling of squeeze-film damping forperforated circular microplates, Journalof Sound and Vibration 333 (2014) 2688-2700. [6] PuLi*(李普), Rufu Hu, A model for squeeze-film damping of perforated MEMS devices in the freemolecular regime,Journal of Micromechanicsand Microengineering, 21 (2011) 025006. [7] Pu Li*(李普), Yuming Fang(方玉明), A moleculardynamics simulation approach for the squeeze-film damping of MEMS devices inthe free molecular regime, Journal ofMicromechanics and Microengineering, 20 ( 2010) 035005. [8] Pu Li*(李普), Rufu Hu, Yuming Fang(方玉明), A new model for squeeze-film dampingsqueeze-film damping of electrically actuated microbeamunder the effect of a static deflection, Journal of Micromechanics and Microengineering, 17 (2007)1242-1251. [9] Pu Li*(李普), Rufu Hu, On the airdamping of flexible microbeam in free space at the free-molecule regime, Microfluidics and Nanofluidics,(2007) 3: 715-721. [10] PuLi*(李普), Yuming Fang(方玉明), An Analytical Model forSqueeze-Film Damping of Perforated Torsional Microplates Resonators, Sensors, 2015, 15(4), 7388-7411.
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