# Atomically flat single terminated oxide substrate surfaces

**Authors:** Abhijit Biswas, Chan Ho Yang, Ramamoorthy Ramesh, Yoon H Jeong

arXiv: 1705.03436 · 2017-05-30

## TL;DR

This review discusses methods to prepare atomically flat, single-terminated oxide substrates crucial for high-quality epitaxial oxide film growth, focusing on practical procedures for various commercially available materials.

## Contribution

It systematically summarizes surface treatment techniques to achieve atomically flat, single-terminated oxide substrates, emphasizing experimental practicality and material-specific procedures.

## Key findings

- Most substrates can achieve atomically flat, single termination surfaces.
- Surface selectivity enables exploration of new phenomena in oxide heterostructures.
- Procedures vary based on substrate material and surface chemistry.

## Abstract

To achieve high quality epitaxial thin films and heterostructures of transition metal oxides with atomically controlled interfaces, one critical requirement is the use of atomically flat single terminated oxide substrates since the atomic arrangements and the reaction chemistry of the topmost surface layer of substrates determine the growth and consequent properties of the overlying films. Achieving the atomically flat and chemically single terminated surface state of commercially available substrates, however, requires judicious efforts because the surface of as-received substrates is of chemically mixed nature and also often polar. In this review, we summarize the surface treatment procedures to accomplish atomically flat surfaces with single terminating layer for various metal oxide substrates. We particularly focus on the substrates with lattice constant ranging from 4.00 to 3.70 angstrom, as the lattice constant of most perovskite materials falls into this range. For materials outside the range, one can utilize the substrates to induce compressive or tensile strain on the films and explore new states not available in bulk. The substrates covered in this review, which have been chosen with commercial availability and, most importantly, experimental practicality as a criterion, are KTaO3, REScO3 (RE = Rare-earth elements), SrTiO3, La0.18Sr0.82Al0.59Ta0.41O3 (LSAT), NdGaO3, LaAlO3, SrLaAlO4, and YAlO3. Analyzing all the established procedures, we conclude that atomically flat surfaces with selective A- or B-site single termination would be obtained for most commercially available oxide substrates. We further note that this topmost surface layer selectivity would provide an additional degree of freedom in searching for unforeseen emergent phenomena and functional applications in epitaxial oxide thin films and heterostructures with atomically controlled interfaces.

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Source: https://tomesphere.com/paper/1705.03436