Dynamical behavior of integro-differential boundary value problem arising in nano-structures via Cellular Nanoscale Network approach

G. Agranovich; E. Litsyn; A. Slavova

doi:10.1016/j.cam.2018.11.024

Dynamical behavior of integro-differential boundary value problem arising in nano-structures via Cellular Nanoscale Network approach

G. Agranovich, E. Litsyn, A. Slavova

Department of Electrical and Electronics Engineering

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Piezoelectrical solid with nano-holes under time-harmonic anti-plane load is studied in the paper. The model is defined by the system of two partial differential equations and the boundary conditions which define the generalized stress. We reduce the model into an integro-differential boundary value problem and construct Cellular Nanoscale Network (CNN) architecture. Dynamical behavior of the obtained CNN model is studied by means of describing function technique. The simulations are provided which illustrate the theoretical results. The results of this paper are applicable in the field of non-destructive testing and fracture mechanics of multi-functional materials and structural elements based on them.

Original language	English
Pages (from-to)	62-71
Number of pages	10
Journal	Journal of Computational and Applied Mathematics
Volume	352
DOIs	https://doi.org/10.1016/j.cam.2018.11.024
State	Published - 15 May 2019

Keywords

Cellular nanoscale network
Describing function technique
Integro-differential boundary value problem
Piezoelectric finite solid

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10.1016/j.cam.2018.11.024

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title = "Dynamical behavior of integro-differential boundary value problem arising in nano-structures via Cellular Nanoscale Network approach",

abstract = "Piezoelectrical solid with nano-holes under time-harmonic anti-plane load is studied in the paper. The model is defined by the system of two partial differential equations and the boundary conditions which define the generalized stress. We reduce the model into an integro-differential boundary value problem and construct Cellular Nanoscale Network (CNN) architecture. Dynamical behavior of the obtained CNN model is studied by means of describing function technique. The simulations are provided which illustrate the theoretical results. The results of this paper are applicable in the field of non-destructive testing and fracture mechanics of multi-functional materials and structural elements based on them.",

keywords = "Cellular nanoscale network, Describing function technique, Integro-differential boundary value problem, Piezoelectric finite solid",

author = "G. Agranovich and E. Litsyn and A. Slavova",

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T1 - Dynamical behavior of integro-differential boundary value problem arising in nano-structures via Cellular Nanoscale Network approach

AU - Agranovich, G.

AU - Litsyn, E.

AU - Slavova, A.

PY - 2019/5/15

Y1 - 2019/5/15

N2 - Piezoelectrical solid with nano-holes under time-harmonic anti-plane load is studied in the paper. The model is defined by the system of two partial differential equations and the boundary conditions which define the generalized stress. We reduce the model into an integro-differential boundary value problem and construct Cellular Nanoscale Network (CNN) architecture. Dynamical behavior of the obtained CNN model is studied by means of describing function technique. The simulations are provided which illustrate the theoretical results. The results of this paper are applicable in the field of non-destructive testing and fracture mechanics of multi-functional materials and structural elements based on them.

AB - Piezoelectrical solid with nano-holes under time-harmonic anti-plane load is studied in the paper. The model is defined by the system of two partial differential equations and the boundary conditions which define the generalized stress. We reduce the model into an integro-differential boundary value problem and construct Cellular Nanoscale Network (CNN) architecture. Dynamical behavior of the obtained CNN model is studied by means of describing function technique. The simulations are provided which illustrate the theoretical results. The results of this paper are applicable in the field of non-destructive testing and fracture mechanics of multi-functional materials and structural elements based on them.

KW - Cellular nanoscale network

KW - Describing function technique

KW - Integro-differential boundary value problem

KW - Piezoelectric finite solid

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Dynamical behavior of integro-differential boundary value problem arising in nano-structures via Cellular Nanoscale Network approach

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