Galvanic Corrosion in Silicon Microsystems: Finite Element Simulation Tool Development

Abstract

Many microsystems fabrication technologies currently employ a metallic overlayer, such as gold, in electrical contact with silicon (Si) structural layers. During postprocessing in hydrofluoric acid based solutions, a galvanic cell is created between the silicon and the metallic layer. As a consequence, autonomous corrosion (etching) of the silicon layer occurs forming nanoscale porosity at the thin film surface and grain boundaries. Over the past 24 months, our ARO sponsored work on microfabricated polycrystalline silicon (polySi) and single crystal Si (SCS) shows that electrochemical corrosion can significantly degrade key operational characteristics including stiffness, strength, electrical resistance, and surface morphology. Following characterization and quantification of Si corrosion, we have developed a corrosion simulation tool for microsystems that can be used to predict property degradation including modulus and fracture strength. Designers can also use this model to identify corrosion susceptible device geometries, enabling subsequent design alteration to reduce corrosion or limit corrosion to non-critical areas of the device. The end goal of this research effort being the realization of unprecedented material properties and performance in Si based MEMS through rational design, testing, and simulation.

Document Details

Document Type

Technical Report

Publication Date

Aug 28, 2009

Accession Number

ADA512550

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