2021
DOI: 10.3390/nano11092270
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The Effect of Micro-Inertia and Flexoelectricity on Love Wave Propagation in Layered Piezoelectric Structures

Abstract: The non-classical linear governing equations of strain gradient piezoelectricity with micro-inertia effect are used to investigate Love wave propagation in a layered piezoelectric structure. The influence of flexoelectricity and micro-inertia effect on the phase wave velocity in a thin homogeneous flexoelectric layer deposited on a piezoelectric substrate is investigated. The dispersion relation for Love waves is obtained. The phase velocity is numerically calculated and graphically illustrated for the electri… Show more

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Cited by 22 publications
(2 citation statements)
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“…and the electric potential is the same as used previously Equation (). The importance of taking in consideration the effects of microinertia on the dynamical behavior of materials was highlighted by several authors (see [45, 62, 63], for example). The following figures present a comparison between the state variables for three values of the ratio h/l0$h/\mathcal{l}_0$…”
Section: Numerical Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…and the electric potential is the same as used previously Equation (). The importance of taking in consideration the effects of microinertia on the dynamical behavior of materials was highlighted by several authors (see [45, 62, 63], for example). The following figures present a comparison between the state variables for three values of the ratio h/l0$h/\mathcal{l}_0$…”
Section: Numerical Resultsmentioning
confidence: 99%
“…The electric boundary conditions are categorized into electric potential and electric surface charge density. Most researchers [43][44][45] classified the electric potential into two cases: open circuit, where there is no charge on the vacuum enclosing the domain, and short-circuit, where there is a given value for the potential in the vacuum surrounding the body. Here we choose a linear function for the electric potential in the vacuum (short-circuit) and neglect electric surface charge density at the boundary.…”
Section: The Boundary Conditionsmentioning
confidence: 99%