# Role of disorder and correlations in metal-insulator transition in   ultrathin SrVO3 films

**Authors:** Gaomin Wang, Zhen Wang, Meng Meng, Mohammad Saghayezhian, Lina Chen,, Chen Chen, Hangwen Guo, Yimei Zhu, Ward Plummer, and Jiandi Zhang

arXiv: 1904.05726 · 2019-10-16

## TL;DR

This study investigates the metal-insulator transition in ultrathin SrVO3 films, revealing that disorder caused by oxygen vacancies and lattice distortions, rather than electron correlations, primarily drives the transition at a critical thickness of about 3 unit cells.

## Contribution

The paper demonstrates that disorder, not electron correlations, is the main factor behind the thickness-induced MIT in SrVO3 ultrathin films, highlighting the role of oxygen vacancies and structural distortions.

## Key findings

- MIT occurs at ~3 unit cells thickness
- Disorder due to oxygen vacancies correlates with MIT
- Electron correlations are less influential in MIT

## Abstract

Metallic oxide SrVO3 represents a prototype system for the study of the mechanism behind thickness-induced metal-to-insulator transition (MIT) or crossover in thin films due to its simple cubic symmetry with one electron in the 3d state in the bulk. Here we report a deviation of chemical composition and distortion of lattice structure existing in the initial 3 unit cells of SrVO3 films grown on SrTiO3 (001) from its bulk form, which shows a direct correlation to the thickness-dependent MIT. In-situ photoemission and scanning tunneling spectroscopy indicate a MIT at the critical thickness of ~3 unit cell (u.c.), which coincides with the formation of a (root2Xroot2)R45 surface reconstruction. However, atomically resolved scanning transmission electron microscopy and electron energy loss spectroscopy show depletion of Sr, change of V valence, thus implying the existence of a significant amount of oxygen vacancies in the 3 u.c. of SrVO3 near the interface. Transport and magneto-transport measurements further reveal that disorder, rather than electron correlations, is likely to be the main cause for the MIT in the SrVO3 ultrathin films.

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Source: https://tomesphere.com/paper/1904.05726