Nonlinear oscillation of nanoelectro-mechanical resonators using energy balance method: considering the size effect and the van der Waals force

Ghalambaz, Mohammad; Ghalambaz, Mehdi; Edalatifar, Mohammad

doi:10.1007/s13204-015-0445-3

Cited by 13 publications

(14 citation statements)

References 27 publications

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“…The nonlinear vibration of an electrostatically-actuated nanobeam with van der Waals, Casimir and fringing effects can be modelled as (Ghalambaz et al, 2016):…”

Section: Electrostatically-actuated Nanobeam With Weak Interacting Forcesmentioning

confidence: 99%

“…The error analysis of Figure 2b showed that the nanobeam undergoes a linear to weakly nonlinear response for 0 < < 0.35, while a strong nonlinear response was predicted when > 0.475. Equations ( 8) was studied by Ghalambaz et al (2016) using the energy balance method (EBM) while Ismail et al (2019) used the global residue harmonic balance method (GRHBM). The EBM solution was simulated for = 0.01 while the GRHBM was applied for ≤ 0.50.…”

Section: Electrostatically-actuated Nanobeam With Weak Interacting Forcesmentioning

confidence: 99%

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Energy-Based Criterion for Testing the Nonlinear Response Strength of Strong Nonlinear Oscillators

Big‐Alabo¹

2021

jasem

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This article proposes a simple energy-based criterion developed to characterize four commonly identified responses, namely: linear, weakly nonlinear, moderately nonlinear and strongly nonlinear regimes. The response of the nonlinear simple pendulum was used for benchmarking the boundary conditions for each of the four response regimes and the test criterion was demonstrated using relevant examples. The test presented in this article is important for clarifying the obscurity surrounding the accuracy and range of validity of recent approximate analytical schemes used to investigate strong nonlinear oscillators. Furthermore, it is meant to create awareness of the need to develop more robust testing criteria. Keywords: strong nonlinear oscillation; periodic oscillation; approximate analytical solution

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“…The nonlinear vibration of an electrostatically-actuated nanobeam with van der Waals, Casimir and fringing effects can be modelled as (Ghalambaz et al, 2016):…”

Section: Electrostatically-actuated Nanobeam With Weak Interacting Forcesmentioning

confidence: 99%

Section: Electrostatically-actuated Nanobeam With Weak Interacting Forcesmentioning

confidence: 99%

Energy-Based Criterion for Testing the Nonlinear Response Strength of Strong Nonlinear Oscillators

Big‐Alabo¹

2021

jasem

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“…Moreover, the BVP (1), (2) has been analyzed by meshless method through radial basis functions, though they are often used for high-dimensional problems [22][23][24][25][26][27][28][29][30][31][32][33][34][35]. The interested readers are also referred to [36][37][38][39] for other useful techniques, which can be applied for the same problems.…”

Section: Preliminaries and Mathematical Formulationmentioning

confidence: 99%

Buckling of Doubly Clamped Nano-Actuators in General Form through Optimized Chebyshev Polynomials with Interior Point Algorithm

Shivanian

Ansari

2019

Acta Phys. Pol. A

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In current work, a novel intelligent computational technique is adopted for searching the behaviour of the problem of buckling of nano-actuators in the presence of various nonlinear forces. In order to accomplish this aim, the governing integro-differential equation in general form is taken into account for nano-actuators, which contains various nonlinear forces as well. This generalized form for the nano-actuators is in fact a non-linear fourth-order Fredholm integro-differential boundary value problem. The boundary value problem is transformed into an equivalent problem whose boundary conditions are such that it is convenient to apply reformed version of the Chebyshev polynomials of the first kind. These Chebyshev polynomials based functions construct approximate series solution with unknown weights. The mathematical formulation of optimization problem consists of an uninspected error which is minimized through adjusting weights via interior point method. The trial approximate solution is validated by imposing tolerance constrained into optimization problem. This numerical technique enables us to overcome all kind of nonlinearities in the mentioned boundary value problem, and then to obtain an accurate solution. Thus, it can expedite the design of nano-actuators.

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“…biosensors, micro-resonators, atomic force microscopes (AFMs) and actuators [1][2][3][4]. MEMS/NEMS may be actuated using several sources of energy such as electrostatic [5], electromagnetic [6], piezoelectric [7] and may be made of metals or polymer, silicon-based structures or functionally graded materials (FGM) [8][9][10][11][12][13]. Electrostatic actuation has demonstrated good energy density and efficiency.…”

Section: Introductionmentioning

confidence: 99%

Static and Dynamic Pull-In Instability of Nano-Beams Resting on Elastic Foundation Based on the Nonlocal Elasticity Theory

Sedighi

Sheikhanzadeh

2017

Chin. J. Mech. Eng.

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This paper provides the static and dynamic pullin behavior of nano-beams resting on the elastic foundation based on the nonlocal theory which is able to capture the size effects for structures in micron and sub-micron scales. For this purpose, the governing equation of motion and the boundary conditions are driven using a variational approach. This formulation includes the influences of fringing field and intermolecular forces such as Casimir and van der Waals forces. The differential quadrature (DQ) method is employed as a high-order approximation to discretize the governing nonlinear differential equation, yielding more accurate results with a considerably smaller number of grid points. In addition, a powerful analytical method called parameter expansion method (PEM) is utilized to compute the dynamic solution and frequency-amplitude relationship. It is illustrated that the first two terms in series expansions are sufficient to produce an acceptable solution of the mentioned structure. Finally, the effects of basic parameters on static and dynamic pull-in instability and natural frequency are studied.

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Nonlinear oscillation of nanoelectro-mechanical resonators using energy balance method: considering the size effect and the van der Waals force

Cited by 13 publications

References 27 publications

Energy-Based Criterion for Testing the Nonlinear Response Strength of Strong Nonlinear Oscillators

Energy-Based Criterion for Testing the Nonlinear Response Strength of Strong Nonlinear Oscillators

Buckling of Doubly Clamped Nano-Actuators in General Form through Optimized Chebyshev Polynomials with Interior Point Algorithm

Static and Dynamic Pull-In Instability of Nano-Beams Resting on Elastic Foundation Based on the Nonlocal Elasticity Theory

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