Nonlinear dynamic analysis of a V-shaped microcantilever of an atomic force microscope

This paper is devoted to investigate the nonlinear behaviors of a V-shaped microcantilever of an atomic force microscope (AFM) operating in its two major modes: amplitude modulation and frequency modulation. The nonlinear behavior of the AFM is due to the nonlinear nature of the AFM tip–sample inter...

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Bibliographic Details
Published in:Applied mathematical modelling 2011-12, Vol.35 (12), p.5903-5919
Main Authors: Kahrobaiyan, M.H., Rahaeifard, M., Ahmadian, M.T.
Format: Article
Language:English
Subjects:
Amplitude modulation mode
Atomic force microscope
Atomic force microscopes
Atomic force microscopy
Exact sciences and technology
Frequency modulation mode
Fundamental areas of phenomenology (including applications)
Galerkin methods
Instruments, apparatus, components and techniques common to several branches of physics and astronomy
Mathematical analysis
Mathematical models
Mechanical instruments, equipment and techniques
Method of multiple scales
Micromechanical devices and systems
Nonlinear dynamic analysis
Nonlinearity
Partial differential equations
Physics
Scanning probe microscopes, components and techniques
Solid mechanics
Structural and continuum mechanics
V-shaped microcantilever
Vibration, mechanical wave, dynamic stability (aeroelasticity, vibration control...)
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Summary:This paper is devoted to investigate the nonlinear behaviors of a V-shaped microcantilever of an atomic force microscope (AFM) operating in its two major modes: amplitude modulation and frequency modulation. The nonlinear behavior of the AFM is due to the nonlinear nature of the AFM tip–sample interaction caused by the Van der Waals attraction/repulsion force. Considering the V-shaped microcantilever as a flexible continuous system, the resonant frequencies, mode shapes, governing nonlinear partial and ordinary differential equations (PDE and ODE) of motion, boundary conditions, frequency and time responses, potential function and phase-plane of the system are obtained analytically. The governing PDE is determined by employing the Hamilton principle. Subsequently, the Galerkin method is utilized to gain the governing nonlinear ODE. Afterward, the resulting ODE is analytically solved by means of some perturbation techniques including the method of multiple scales and the Lindsted–Poincare method. In addition, the effects of different parameters including geometrical one on the frequency response of the system are assessed.
ISSN:0307-904X
DOI:10.1016/j.apm.2011.05.039