Design and Realization of Ohmic and Schottky Interfaces for Oxide Electronics

Understanding band alignment and charge transfer at complex oxide interfaces is critical to tailoring and utilizing their diverse functionality. Toward this goal, both Ohmic- and Schottky-like charge transfers at oxide/oxide semiconductor/metal interfaces are designed and experimentally validated. A method for predicting band alignment and charge transfer in ABO(3) perovskites is utilized, where previously established rules for simple semiconductors fail. The prototypical systems chosen are the rare class of oxide metals, SrBO3 with B = V-Ta, when interfaced with the multifaceted semiconducting oxide, SrTiO3. For B = Nb and Ta, it is confirmed that a large accumulation of charge occurs in SrTiO3 due to the higher energy Nb and Ta states relative to Ti. This gives rise to a high mobility metallic interface, which is an ideal epitaxial oxide/oxide Ohmic contact. On the contrary, for B = V, there is no charge transfer into the SrTiO3 interface, which serves as a highly conductive epitaxial gate metal. Going beyond these specific cases, this work opens the door to integrating the vast phenomena of ABO(3) perovskites into a wide range of practical devices.

Automated summary

Understanding band alignment and charge transfer at complex oxide interfaces is crucial for utilizing their diverse functionality. This study investigates and validates the charge transfers at oxide/oxide semiconductor/metal interfaces, and proposes a method for predicting band alignment and charge transfer in ABO(3) perovskites.