ANALYZING A BIMORPH PIEZOELECTRIC NANOSCALE ACTUATOR UNDER PRIMARY-RESONANCE EXCITATION

In this study, nonlinear forced vibrations of a bimorph piezoelectric nanobeam are investigated by using the nonlocal elasticity theory. This nanoactuator is modeled using the Euler-Bernoulli beam theory. The Hamilton principle is used to obtain the equations of motion. The derived equations are discretized by applying the mode shapes of multi-span beams as test functions in the Galerkin decomposition method. The discretized equations are then solved using the perturbation method. A parametric study is conducted to show the significance of size effects on the dynamic behavior of nanoactuators. The results show that an increase in the nonlocal parameter leads to a decrease in the fundamental natural frequency of the nanobeam and to an increase in the response amplitude.

Automated summary

In this study, the nonlinear forced vibrations of a bimorph piezoelectric nanobeam were investigated using the nonlocal elasticity theory. The nanobeam was modeled using Euler-Bernoulli beam theory, and the equations of motion were obtained using the Hamilton principle. The derived equations were discretized using the Galerkin decomposition method with mode shapes of multi-span beams as test functions. The results of the study showed that size effects significantly influenced the dynamic behavior of the nanoactuators, with an increase in the nonlocal parameter leading to a decrease in the fundamental natural frequency of the nanobeam and an increase in the response amplitude.