Nonlocal Thermoelasticity Theory for Thermal-Shock Nanobeams with Temperature-Dependent Thermal Conductivity

Authors

A. M. Zenkour, King Abdulaziz University
A. E. Abouelregal, Mansoura University
K. A. Alnefaie, King Abdulaziz University
X. Zhang, Southwest Jiaotong University
E. C. Aifantis, King Abdulaziz University

Document Type

Article

Publication Date

1-1-2015

Abstract

© 2015 Taylor and Francis Group, LLC. In this work, a model of nonlocal generalized thermoelasticity with one thermal relaxation time is used to consider the vibration behavior of an Euler-Bernoulli (E-B) nanobeam. The thermal conductivity of the nanobeam is assumed to be temperature-dependent. The nonlocality brings in an internal length scale in the formulation and, thus, allows for the interpretation of size effects. The governing partial differential equations are solved in the Laplace transform domain by adopting the state-space approach of modern control theory. The inverse of Laplace transforms are numerically computed using Fourier expansion techniques. The distributions of the lateral vibration, the temperature, the axial displacement and the bending moment of the nanobeam are determined. The effect of thickness and variability of thermal conductivity, as well as the influence of the nonlocal parameter are investigated.

Publication Title

Journal of Thermal Stresses

Recommended Citation

Zenkour, A., Abouelregal, A., Alnefaie, K., Zhang, X., & Aifantis, E. (2015). Nonlocal Thermoelasticity Theory for Thermal-Shock Nanobeams with Temperature-Dependent Thermal Conductivity. Journal of Thermal Stresses, 38(9), 1049-1067. http://doi.org/10.1080/01495739.2015.1038490
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p/9175