Nonlinear vibration of piezoelectric laminated nanobeams at higher modes based on nonlocal piezoelectric theory
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O R I G I NA L PA P E R
M. Nazemizadeh · F. Bakhtiari-Nejad · A. Assadi · B. shahriari
Nonlinear vibration of piezoelectric laminated nanobeams at higher modes based on nonlocal piezoelectric theory
Received: 25 September 2019 / Revised: 7 May 2020 © Springer-Verlag GmbH Austria, part of Springer Nature 2020
Abstract The presented paper investigates the nonlinear vibration of a nanobeam with a piezoelectric layer bounded to its top surface considering the nonlocal piezoelectricity theory. To do this, Hamilton’s principle is implemented to derive the governing nonlinear vibration equations of the nanobeam by assumption of nonlocal piezoelectricity and a nonlinear strain–displacement relation. Then, the Galerkin separation method is applied to transform and simplify the partial differential equation of the nonlinear oscillation to an ordinary one with quadratic and cubic nonlinearities in the time domain. By implementing the multiple-scale perturbation method, an analytical relation for the nonlinear natural frequencies is obtained as a function of the oscillation amplitude and the nonlocal size scale parameter. Then, the nonlinear vibration characteristics of the nanobeam are investigated at higher modes of vibration and the size scale effects are reviewed comprehensively. It is observed that the nonlocal parameter decreases the nonlinear natural frequencies and becomes noticeable at higher modes of vibration. Moreover, by increasing the amplitude ratio, the nonlocal effects are decreased and the nonlocal nonlinear frequency approaches the local one. Also, the amplitude ratio has increasing effects on the nonlinear frequencies.
1 Introduction Recent remarkable developments in science and technology have provided the ability to fabricate smallsize devices and systems with micron to submicron dimensions [1]. Concerning these modern technologies, micro-/nanobeams with characteristic dimension in micro-to-nanoscales emerged in the micro-/ nanotechnology [2]. Currently, micro-/nanobeams play a key role in micro-/nanosystems due to several characteristics including small size, low energy consumption, high-frequency operation, and simple fabrication M. Nazemizadeh (B) · A. Assadi · B. shahriari Faculty of Mechanics, Malek Ashtar University of Technology, Shahin Shahr, Iran E-mail: [email protected] A. Assadi E-mail: [email protected] B. shahriari E-mail: [email protected] F. Bakhtiari-Nejad Department of Mechanical Engineering, University of Maryland, Maryland, USA E-mail: [email protected] F. Bakhtiari-Nejad Department of Mechanical Engineering, Amirkabir University of Technology, Tehran, Iran E-mail: [email protected]
M. Nazemizadeh et al.
despite small-scale joints. Therefore, these micro-to-nanoscale beams are widely utilized in several modern technologies including micro-/nanoresonators, atomic force microscopes (AFM), micro-/nanoswitches, biosensors, nano-/microelectromechanical systems (NEMS/MEMS), etc. [2,3]. Also, the application of piezoelectric micro-/nanobeams as electromechanical resonators is
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