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Dynamics of graphene origami-enabled auxetic metamaterial beams via various shear deformation theories

Behrouz Karami, Mergen H. Ghayesh

2024International Journal of Engineering Science48 citationsDOIOpen Access PDF

Abstract

Although auxetic metamaterials exhibit unique and unusual mechanical properties, such as a negative Poisson's ratio, their mechanics remains poorly understood. In this study, we model a graded beam fabricated from graphene origami-enabled auxetic metamaterials and investigate its dynamics from the perspective of different shear deformation theories. The auxetic metamaterial beam is composed of multiple layers of graphene origami-enabled auxetic metamaterials, where the content of graphene origami varies through the layered thickness; both the auxetic property and other properties are varied in a graded manner, which are effectively be approximated via micromechanical models. The Euler-Bernoulli, third-order, and higher-order shear deformable refined beam theories are adopted to model the auxetic metamaterial beam as a continuous system. Following this, the governing motion equations are derived using the Hamiltonian principle and then are numerically solved using a weighted residual method. The obtained results provide a comprehensive understanding of how graphene origami content and its distribution pattern, graphene folding degree, and the utilisation of different shear deformation theories influence the dynamic behaviour of the beam.

Topics & Concepts

AuxeticsMetamaterialMaterials scienceGrapheneTimoshenko beam theoryShear (geology)Beam (structure)Composite materialMechanicsNanotechnologyPhysicsOpticsOptoelectronicsCellular and Composite StructuresAdvanced Materials and MechanicsVibration Control and Rheological Fluids