Hyperelastic Microcantilever AFM: Efficient Detection Mechanism Based on Principal Parametric Resonance

Abstract: The impetus of writing this paper is to propose an efficient detection mechanism to scan the surface profile of a micro-sample using cantilever-based atomic force microscopy (AFM), operating in non-contact mode. In order to implement this scheme, the principal parametric resonance characteristics of the resonator are employed, benefiting from the bifurcation-based sensing mechanism. It is assumed that the microcantilever is made from a hyperelastic material, providing large deformation under small excitation a… Show more

“…A time integration-based solver is utilized to solve the resulting equations. Alibakhshi et al [ 22 ] elaborated on a suitable detection mechanism for scanning the surface profile of a micro-sample by AFM, considering that the probe is made of a hyperelastic material. Falope et al [ 23 ] proposed a finite element-based theoretical model to study the bending behavior of a hyperelastic solid.…”

Viscoelasticity in Large Deformation Analysis of Hyperelastic Structures

“…A time integration-based solver is utilized to solve the resulting equations. Alibakhshi et al [ 22 ] elaborated on a suitable detection mechanism for scanning the surface profile of a micro-sample by AFM, considering that the probe is made of a hyperelastic material. Falope et al [ 23 ] proposed a finite element-based theoretical model to study the bending behavior of a hyperelastic solid.…”

Viscoelasticity in Large Deformation Analysis of Hyperelastic Structures

Influence of surface effect on post-buckling behavior of graded porous nanobeam subjected to follower force

Nonlinear vibration and dynamic stability of dielectric sandwich micro-beams