# GaAs Nanowire Growth by MBE with Catalyst Forming Eutectic Points with Both Elements

**Authors:** Nickolay V. Sibirev, Ilya P. Soshnikov, Igor V. Ilkiv, Evgenii V. Ubyivovk, George E. Cirlin, Igor V. Shtrom

PMC · DOI: 10.3390/nano15211664 · 2025-11-01

## TL;DR

This paper explores a new method for growing GaAs nanowires using tin as a catalyst, which allows for better control and avoids issues seen with traditional catalysts.

## Contribution

The paper demonstrates, for the first time, GaAs nanowire growth using a tin catalyst via molecular beam epitaxy.

## Key findings

- Tin can act as a catalyst for GaAs nanowire growth and as a nucleation site.
- Two types of tin catalysts (Ga-rich and Ga-poor) are observed during growth.
- Annealing tin on substrates forms metal droplets below 450 °C and dissolves tin at higher temperatures.

## Abstract

A3B5 nanowires are usually grown via the vapor-liquid-solid mechanism. Species from the vapor are incorporated into the nanowires using a catalyst droplet. Typically, the droplet is a low-melting-point eutectic alloy of catalyst and group III metal. This growth imposes a set of limitations on the heterostructure formation and doping. Axial A3B5 heterostructure nanowires obtained via an interchange of group III metals suffer from blurring and kinking. Amphoteric dopants such as Si could act as donors and acceptors, leading to electron-to-hole ratio oscillations along the nanowire. To overcome these limits, the growth with a catalyst, which could dissolve both components of the nanowire, is studied. Tin has a eutectic with both components, As and Ga. This makes the growth of GaAs nanowires with a tin catalyst different from that with standard catalysts. Nanowire growth occurs with at least two types of catalysts, Ga-rich and Ga-poor (As-rich). This article aims to study the nanowire growth with an Sn catalyst. For the first time, the growth of GaAs nanowires using a tin catalyst by molecular beam epitaxy is shown. Tin can serve as a catalyst not only for the chemical growth of GaAs nanowires but also as a nucleation site for their growth. Both compositions of the catalyst are observed. The annealing of a thin film of tin on a Si and GaAs substrate has also been studied. At temperatures below 450 °C, small metal droplets form, while tin dissolves into the substrate at higher temperatures.

## Linked entities

- **Chemicals:** GaAs (PubChem CID 14770), Sn (PubChem CID 104883), As (PubChem CID 1549433), Ga (PubChem CID 5360835)

## Full-text entities

- **Chemicals:** A3B5 (-), Ga (MESH:D005708), GaAs (MESH:C043055), Si (MESH:D012825), As (MESH:D001151), Sn (MESH:D014001), metal (MESH:D008670)

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12608681/full.md

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Source: https://tomesphere.com/paper/PMC12608681