Thermoelastic fractional derivative model for exciting viscoelastic microbeam resting on Winkler foundation

In the current investigation, the thermoelastic vibration of a viscoelastic microbeam resting on the Winkler foundation is studied using the fractional-order theory. To describe the damping of the viscoelastic material according to experimental results, the Kelvin-Voigt model is replaced by a new form with a fractional-order derivative. The generalized thermoelasticity model and Euler-Bernoulli beam theory are used to construct the governing equation. The microbeam is subjected to axial load, ultrafast laser heating, and varying sinusoidal heat. The governing equation is then solved using the Laplace transform technique to determine the deflection and thermoelastic interaction responses of microbeams. The effects of many parameters such as the coefficient of viscosity, axial load, fractional derivative order, laser pulse duration, and foundation parameter on the microbeam response are explained and discussed in detail.

Automated summary

This study investigates the thermoelastic vibration of a viscoelastic microbeam resting on the Winkler foundation using fractional-order theory, replacing the Kelvin-Voigt model with a new form. The effects of various parameters on the microbeam response, such as viscosity coefficient, axial load, fractional derivative order, laser pulse duration, and foundation parameter, are explained and discussed in detail.