Superconductivity in the bcc-type High-entropy Alloy TiHfNbTaMo

TL;DR

This study investigates the structure and superconducting properties of a novel bcc-type high-entropy alloy TiHfNbTaMo, revealing its superconductivity at 3.42 K and analyzing its electronic structure through experiments and calculations.

Contribution

It provides the first detailed characterization of superconductivity in TiHfNbTaMo high-entropy alloy, combining experimental and theoretical insights.

Findings

TiHfNbTaMo has a bcc structure with homogeneous element distribution.

The alloy exhibits type-II superconductivity at Tc = 3.42 K.

Electronic structure features van Hove singularities and hybrid d orbitals.

Abstract

X-ray powder diffraction, electrical resistivity, magnetization, and thermodynamic measurements were conducted to investigate the structure and superconducting properties of TiHfNbTaMo, a novel high-entropy alloy possessing a valence electron count (VEC) of 4.8. The TiHfNbTaMo HEA was discovered to have a body-centered cubic structure and a microscopically homogeneous distribution of the constituent elements. This material shows type-II superconductivity with Tc = 3.42 K, lower critical field with 22.8 mT, and upper critical field with 3.95 T. Low-temperature specific heat measurements show that the alloy is a conventional s-wave type with a moderately coupled superconductor. First-principles calculations show that the density of states (DOS) of the TiHfNbTaMo alloy is dominated by hybrid d orbitals of these five metal elements. Additionally, the TiHfNbTaMo HEA exhibits three van Hove singularities. Furthermore, the VEC and the composition of the elements (especially the Nb elemental content) affect the Tc of the bcc-type HEA.