Electromechanical coupling characteristics of double-layer piezoelectric quasicrystal actuators

Electromechanical coupling characteristics of double-layer piezoelectric quasicrystal micro/nano-actuator are investigated by considering the effects of nanoscale interactions and nonlocal scale. The analytical models in the phonon, phason, and electric fields are derived via state vector formulation and propagator matrix method based on quasicrystal nonlocal elasticity theory. Governing equations of the models with geometrical nonlinearity are solved using the secant method. All nonlinear effects of the electrostatic force, van der Waals force, Casimir force, and nonlocal parameters on the mechanical behaviors of quasicrystal actuators are studied. Our results show that the increment of van der Waals force and Casimir force enlarges phonon stress and displacement. When the initial gap is larger than 3.72 nm, the effect of van der Waals force is more significant than that of Casimir force. The phonon-phason coupling elastic coefficient and the nonlocal scale parameter respectively have positive and negative effects on the static responses. Besides, the influence of the Casimir force on mechanical behavior depends on the volume ratio and scale of the quasicrystal nano-actuator.

Automated summary

The electromechanical coupling characteristics of a double-layer piezoelectric quasicrystal micro/nano-actuator were studied, with a focus on the effects of van der Waals force and Casimir force on phonon stress and displacement. The study also revealed that the phonon-phason coupling elastic coefficient and nonlocal scale parameter have positive and negative effects on static responses.