Determination of compressive stress in thin films using micro-machined buckled membranes

Abstract

In this work, optical profilometry and finite-element simulations are applied on buckled micro-machined membranes for the stress analysis of ion-beam-sputtered Ta2O5 and SiO2 thin films. Layers with different thicknesses are grown on silicon substrates, then several membranes with different geometries are manufactured with standard micro-system technologies; due to a high level of the films' compressive stress, buckled membranes are obtained. Thermally-grown silica membranes are also produced, for comparison. The residual stress values are determined by comparing the measured and simulated deflections of the membranes. The average stress state of the Ta2O5 thin films is found to be -209 MPa. The SiO2 thin films are in a higher compressive stress state whose average value is -576 MPa. The average stress in thermal SiO2 thin layers grown at 1130 C is found equal to -321 MPa, in good agreement with the literature.