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Thermoelastic damping and frequency shift of different micro-scale piezoelectro-magneto-thermoelastic beams

Sayantan Guha, Abhishek Kumar Singh, Sonam Singh

2023Physica Scripta15 citationsDOIOpen Access PDF

Abstract

Abstract This work focuses on mathematically studying thermoelastic damping (TED) and frequency shift (FS) in micro-scale piezoelectro-magneto-thermoelastic (PEMT) composite beams composed of BaTiO 3 -CoFe 2 O 4 combination. Pertaining to cutting-edge micro-technologies implemented in several engineering/scientific applications now-a-days, micro-scale doubly clamped (CC), doubly simply supported (SS), clamped-free (CF), and clamped-simply supported (CS) beams are extensively analyzed. The beams are modeled following the linear Euler-Bernoulli assumptions. The first two eigenvalues of all beams are numerically obtained using Newton-Raphson method. The closed-form expressions of TED and FS of all beams are derived analytically. The influences of Classical dynamical coupled (CL), Lord-Shulman (LS) & Green-Lindsay (GL) thermoelasticity theories, beam dimensions, BaTiO 3 volume fraction (Ω f ), and the first two modes ( M 1 & M 2 ) on the TED & FS are meticulously analyzed. Critical thickness (CrTh), critical length (CrLt), and TED (inverse Quality factor) of the beams are numerically obtained and studied. Among other key outcomes, the existence of a critical value of Ω f is established in the range Ω f ∈ [0.5, 0.55], at which, the TED and FS display a drastic change in their natures. The outcomes of the present analysis may find immense potential uses in the design and development of PEMT composite micro-beams, and their applications in several areas such as supporting/stiffening other micro/nanostructures, construction works, sensitive sensing applications, etc.

Topics & Concepts

Thermoelastic dampingBeam (structure)StiffeningPhysicsInverseEuler's formulaMaterials scienceEigenvalues and eigenvectorsThermalMathematical analysisThermodynamicsComposite materialMathematicsOpticsGeometryQuantum mechanicsThermoelastic and Magnetoelastic PhenomenaNonlocal and gradient elasticity in micro/nano structuresComposite Structure Analysis and Optimization