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On thermal stability of piezo-flexomagnetic microbeams considering different temperature distributions

Mohammad Malikan, Tomasz Wiczenbach, Victor A. Eremeyev

2021Continuum Mechanics and Thermodynamics40 citationsDOIOpen Access PDF

Abstract

Abstract By relying on the Euler–Bernoulli beam model and energy variational formula, we indicate critical temperature causes in the buckling of piezo-flexomagnetic microscale beams. The corresponding size-dependent approach is underlying as a second strain gradient theory. Small deformations of elastic solids are assessed, and the mathematical discussion is linear. Regardless of the pyromagnetic effects, the thermal loading of the thermal environment varies in three states along with the thickness, which is linear, uniform, and parabolic forms. We then establish the results by developing consistent shape functions that independently evaluate boundary conditions. Next, we analytically develop and explore the effective properties of the studied beam concerning vital factors. It was achieved that piezomagnetic-flexomagnetic microbeams are more affected by the thermal environment while the thermal loading is parabolically distributed across the thickness, particularly when the boundaries involve simple supports.

Topics & Concepts

Microscale chemistryThermalBeam (structure)Boundary value problemMaterials scienceBucklingBoundary (topology)MechanicsBernoulli's principleThermoelastic dampingTimoshenko beam theoryEuler's formulaClassical mechanicsMathematical analysisPhysicsMathematicsOpticsComposite materialThermodynamicsMathematics educationNonlocal and gradient elasticity in micro/nano structuresThermoelastic and Magnetoelastic PhenomenaMechanical and Optical Resonators
On thermal stability of piezo-flexomagnetic microbeams considering different temperature distributions | Litcius