Annealing Induced Interfacial Evolution of Titanium/Gold Metallization on Unintentionally Doped Beta-Ga2O3

Abstract

Here, we study the kinetic evolution of the interface between a Ti/Au metal stack and bulk (010) -Ga2O3 substrate under different annealing conditions using scanning / transmission electron microscopy. We observe distinct processes of interfacial reaction and interdiffusion between the metal films and at the metal-semiconductor junction. Upon rapid thermal annealing (RTA), the as-deposited Ti readily reacts at the Beta-Ga2O3 interface, driven by redox favorability. After a 1-min 470C N2 RTA, the interface exhibits two segregated crystalline layers: a 5 nm Ti-rich (Ti-TiOx) layer lattice-matched to the -Ga2O3 substrate and a 3 nm Ga-rich (TiGax)layer. A substitutional mechanism is proposed based on the similarity in ionic radii of Ti+3, Ti+4, and Ga+3. After 15-min RTA, the Ga-rich layer is diluted within the Ti-Au matrix, while the Ti-TiOx layer does not significantly change, and there is no further observable Ga out-diffusion from the substrate. Thus, we propose that the Ti-TiOx layer acts as a diffusion barrier, even when it is no longer lattice-matched with -Ga2O3. In addition, Ti-rich nanocrystals form within the Ti-Au layer, presumably via the proceeding reactions. The observations here provide insights for contact stack evolution during operation of power electronic devices at elevated temperature.

Document Details

Document Type

Technical Report

Publication Date

Mar 26, 2019

Accession Number

AD1105480

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