# Ultrathin layers of beta-tellurene grown on highly oriented pyrolytic   graphite by molecular-beam epitaxy

**Authors:** Jinglei Chen, Yawei Dai, Yaqiang Ma, Xianqi Dai, Wingkin Ho, Maohai, Xie

arXiv: 1704.07529 · 2017-04-26

## TL;DR

This study experimentally investigates ultrathin tellurium layers grown on graphite, confirming the formation of beta-tellurene with semiconducting properties and thickness-dependent bandgap narrowing.

## Contribution

First experimental epitaxial growth and characterization of beta-tellurene on HOPG, validating theoretical predictions and revealing electronic properties.

## Key findings

- Ultrathin Te layers form beta-tellurene with rectangular surface cells.
- Films are semiconductors with decreasing bandgaps as thickness increases.
- Bandgap narrowing occurs mainly at the valence-band maximum.

## Abstract

Monolayer Tellurium (Te) or tellurene has been suggested by a recent theory as a new two-dimensional (2D) system with great electronic and optoelectronic promises. Here we present an experimental study of epitaxial Te deposited on highly oriented pyrolytic graphite (HOPG) substrate by molecular-beam epitaxy. Scanning tunneling microscopy of ultrathin layers of Te reveals rectangular surface cells with the cell size consistent with the theoretically predicted beta-tellurene, whereas for thicker films, the cell size is more consistent with that of the (10-10) surface of bulk Te crystal. Scanning tunneling spectroscopy measurements show the films are semiconductors with the energy bandgaps decreasing with increasing film thickness, and the gap narrowing occurs predominantly at the valance-band maximum (VBM). The latter is understood by strong coupling of states at the VBM but a weak coupling at conduction band minimum (CBM) as revealed by density functional theory calculations.

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Source: https://tomesphere.com/paper/1704.07529