# Synthesis of Highly Anisotropic Semiconducting GaTe Nanomaterials and   Emerging Properties Enabled by Epitaxy

**Authors:** Hui Cai, Bin Chen, Gang Wang, Emmanuel Soignard, Afsaneh Khosravi,, Marco Manca, Xavier Marie, Shery Chang, Bernhard Urbaszek, and Sefaattin, Tongay

arXiv: 1705.04052 · 2017-05-12

## TL;DR

This paper reports the successful synthesis of highly anisotropic GaTe nanomaterials on various substrates using vapor transport, revealing unique optical and structural properties through advanced microscopy and spectroscopy techniques.

## Contribution

It introduces a novel vapor phase growth method for pseudo-1D GaTe on multiple substrates and provides atomic-scale insights into their anisotropic properties.

## Key findings

- GaTe nanomaterials exhibit highly anisotropic optical responses.
- Defect-related localized emission peaks are observed below the band gap.
- Samples on sapphire show enhanced and narrow emission features.

## Abstract

Pseudo-one dimensional (pseudo-1D) materials are a new-class of materials where atoms are arranged in chain like structures in two-dimensions (2D). Examples include recently discovered black phosphorus, ReS2 and ReSe2 from transition metal dichalcogenides, TiS3 and ZrS3 from transition metal trichalcogenides and most recently GaTe. The presence of structural anisotropy impacts their physical properties and leads to direction dependent light-matter interactions, dichroic optical responses, high mobility channels, and anisotropic thermal conduction. Despite the numerous reports on the vapor phase growth of isotropic TMDCs and post transition metal chalcogenides such as MoS2 and GaSe, the synthesis of pseudo-1D materials is particularly difficult due to the anisotropy in interfacial energy, which stabilizes dendritic growth rather than single crystalline growth with well-defined orientation. The growth of monoclinic GaTe has been demonstrated on flexible mica substrates with superior photodetecting performance. In this work, we demonstrate that pseudo-1D monoclinic GaTe layers can be synthesized on a variety of other substrates including GaAs (111), Si (111) and c-cut sapphire by physical vapor transport techniques. High resolution transmission electron microscopy (HRTEM) measurements, together with angle resolved micro-PL and micro-Raman techniques, provide for the very first time atomic scale resolution experiments on pseudo-1D structures in monoclinic GaTe and anisotropic properties. Interestingly, GaTe nanomaterials grown on sapphire exhibit highly efficient and narrow localized emission peaks below the band gap energy, which are found to be related to select types of line and point defects as evidenced by PL and Raman mapping scans. It makes the samples grown on sapphire more prominent than those grown on GaAs and Si, which demonstrate more regular properties.

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Source: https://tomesphere.com/paper/1705.04052