# Observation of superconducting phase transition in InN

**Authors:** Zhi-Yong Song, Liyan Shang, JunHao Chu, Ping-Ping Chen, Akio Yamamoto, and Ting-Ting Kang

arXiv: 1903.02253 · 2019-03-07

## TL;DR

This study investigates superconducting phase transitions in InN, revealing that grain size and inter-grain coupling are crucial for stable superconductivity, with different behaviors observed depending on sample characteristics.

## Contribution

It demonstrates the influence of grain size and inter-grain coupling on InN superconductivity and clarifies that chemical stability can be achieved through these factors.

## Key findings

- Vortex-glass to liquid transition observed in large grain InN.
- Superconductivity in small grain InN is sensitive to acid etching.
- Large grain size and strong inter-grain coupling enhance stability.

## Abstract

InN superconductivity is very special among III-V semiconductors, because other III-V semiconductor (like GaAs, GaN, InP, InAs etc.) usually lacks strong covalent bonding and seldom shows superconductivity at low-temperature. In this paper, via current-voltage(I-V) measurement, we probe the superconducting phase transitions in InN. The possible connection with those chemical-unstable phase separated inclusions, like metallic indium or In2O3, was removed by HCl acid etching. It finds InN samples can show different phase transition behaviors. The vortex-glass (VG) to liquid transition, which is typical in type-II superconductors, is observed in the sample with large InN grain size. In contrast, the small grain-sized sample's superconducting properties are sensitive to acid etching, shows a transition into a non-zero resistance state at the limit of temperature approaches zero. Our work suggests that the grain size and inter-grain coupling may be two key factors for realizing InN superconductivity. InN superconductivity can become robust and chemical stable if the grain size and inter-grain coupling both are large enough.

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Source: https://tomesphere.com/paper/1903.02253