Correlation between residual stresses and bending in functional electroceramic-based MEMS actuator

Abstract

Micro-electro-mechanical systems (MEMS) technology can offer a viable alternative to realize miniaturized and less expensive actuators for deformable mirror in adaptive optics to obtain high resolution retinal imaging. During fabrication of such devices, functional multilayered thin films are deposited at elevated temperatures. These films are therefore subjected to residual stresses which may result in bending of the structure. The bending thus occurred may lead to failure at interfaces between films. A successful fabrication of device therefore relies on the engineering justification of multi-structured device design and growth parameters used in fabrication. In this paper, we present the design of a piezoelectric (ceramic) thin film based MEMS actuator for deformable mirror used in retinal imaging. A proto-type piezoelectric thin film structure of Pt/PZT/SRO/Pt/γ-Al2O3 has been epitaxially fabricated on Si (111) substrate. Advanced 3D finite element simulations were conducted to correlate the bending of fabricated structure with residual stresses. A smart alternative design was also proposed employing an extra layer of Al–Si (1%) in the diaphragm region. Simulation results predict a failsafe structure when the thickness of extra Al–Si (1%) layer is tailored to an optimal thickness. The outcome of this research can be used to overcome the challenge encountered (bending due to residual stresses) to obtain a failsafe MEMS actuator for deformable mirror.