On the dynamic instability of nanowire-fabricated electromechanical actuators in the Casimir regime: Coupled effects of surface energy and size dependency

• Static and dynamic pull-in instability of a nanowire-fabricated actuator is studied.
• Casimir force is modeled using Drichlet mode assumption.
• The coupled effects of surface energy and size phenomenon are incorporated.
• The higher order surface stress components are incorporated in model.
• The influence of structural damping is considered.

Herein, the dynamic pull-in instability of cantilever nanoactuator fabricated from conductive cylindrical nanowire with circular cross-section is studied under the presence of Casimir force. The Gurtin–Murdoch surface elasticity in combination with the couple stress theory is employed to incorporate the coupled effects of surface energy and size phenomenon. Using Green–Lagrange strain, the higher order surface stress components are incorporated in the governing equation. The Dirichlet mode is considered and an asymptotic solution, based on the path integral approach, is applied to consider the effect of the Casimir attraction. Furthermore, the influence of structural damping is considered in the model. The nonlinear governing equation is solved using analytical reduced order method (ROM). The effects of various parameters on the dynamic pull-in parameters, phase planes and stability threshold of the actuator are demonstrated.

Summary: The coupled influences of the surface energy and size effect on the dynamic pull-in behavior of the nanowire-fabricated nanoactuator operated in the Casimir force regime is investigated.Figure optionsDownload as PowerPoint slide