# Two-dimensional conducting layer on SrTiO$_{3}$ surface induced by   hydrogenation

**Authors:** Y. Takeuchi, R. Hobara, R. Akiyama, A. Takayama, S. Ichinokura, R., Yukawa, I. Matsuda, S. Hasegawa

arXiv: 1904.00539 · 2020-03-04

## TL;DR

Hydrogenation of SrTiO3 creates a unique surface state that induces a two-dimensional conducting layer, with electron donation and band bending, differing from traditional models, and saturates at high hydrogen coverage.

## Contribution

This study reveals a non-rigid, hydrogen-induced surface state on SrTiO3 that forms a two-dimensional conducting layer, challenging conventional band models.

## Key findings

- Hydrogen creates a new in-gap surface state (HDS) on SrTiO3.
- The surface state donates electrons, causing band bending and 2D conduction.
- Conductivity saturates at high hydrogen coverage.

## Abstract

We found that a surface state induced by hydrogenation on the surface of SrTiO$_{3}$(001) (STO) did not obey the rigid band model, which was confirmed by in situ electrical resistivity measurements in ultrahigh vacuum. With exposure of atomic hydrogen on the STO, a new surface state (H-induced donor state, HDS) appears within the bulk band gap (an in-gap state), which donates electrons thermally activated to the bulk conduction band, resulting in downward bending of the bulk bands beneath the surface. The doped electrons flow through the space-charge layer in two-dimensional manner parallel to the surface. The observed semiconducting behavior in the temperature dependence of electronic transport is explained by the thermal activation of carriers. The HDS and the bulk conduction band are non-rigid in energy position; they come closer with increasing the hydrogen adsorption. Eventually the HDS saturates its position around 88 meV below the bottom of the bulk conduction band. The sheet conductivity, accordingly, also saturates at 1.95$\pm$ 0.02 $\mu$ S/sq. with increasing hydrogen adsorption, corresponding to completion of the hydrogenation of the surface.

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Source: https://tomesphere.com/paper/1904.00539