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Thermomechanical Stability of Hyperbolic Shells Incorporating Graphene Origami Auxetic Metamaterials on Elastic Foundation: Applications in Lightweight Structures

Ehsan Arshid

2025Journal of Composites Science13 citationsDOIOpen Access PDF

Abstract

This study presents an analytical investigation of the thermomechanical stability of hyperbolic doubly curved shells reinforced with graphene origami auxetic metamaterials (GOAMs) and resting on a Pasternak elastic foundation. The proposed model integrates shell geometry, thermal–mechanical loading, and architected auxetic reinforcement to capture their coupled influence on buckling behavior. Stability equations are derived using the First-Order Shear Deformation Theory (FSDT) and the principle of virtual work, while the effective thermoelastic properties of the GOAM phase are obtained through micromechanical homogenization as functions of folding angle, mass fraction, and spatial distribution. Closed-form eigenvalue solutions are achieved with Navier’s method for simply supported boundaries. The results reveal that GOAM reinforcement enhances the critical buckling load at low folding angles, whereas higher folding induces compliance that diminishes stability. The Pasternak shear layer significantly improves buckling resistance up to about 46% with pronounced effects in asymmetrically graded configurations. Compared with conventional composite shells, the proposed GOAM-reinforced shells exhibit tunable, folding-dependent stability responses. These findings highlight the potential of origami-inspired graphene metamaterials for designing lightweight, thermally stable thin-walled structures in aerospace morphing skins and multifunctional mechanical systems.

Topics & Concepts

AuxeticsMaterials scienceMorphingMetamaterialComposite materialBucklingGrapheneThermoelastic dampingHomogenization (climate)Orthotropic materialStructural engineeringAerospaceComposite numberStiffnessShear (geology)VibrationContinuum mechanicsShell (structure)Eigenvalues and eigenvectorsElasticity (physics)Asymptotic homogenizationElastic instabilityStructural mechanicsElastic modulusStructural stabilityHoneycomb structureDeformation (meteorology)Microscale chemistryStability (learning theory)Constitutive equationThermal stabilityBraidAdvanced Materials and MechanicsNonlocal and gradient elasticity in micro/nano structuresCellular and Composite Structures