Superconducting susceptibility signal captured in a record wide pressure range

TL;DR

This study reports the first ultrahigh pressure measurements of superconducting diamagnetism in Nb0.44Ti0.56 across a record-wide pressure range, establishing it as a reference for validating superconductivity in compressed hydrides.

Contribution

It introduces Nb0.44Ti0.56 as a reliable reference sample for assessing superconductivity under high pressure, addressing previous measurement challenges.

Findings

Superconducting diamagnetism observed from 5 GPa to 160 GPa.

Nb0.44Ti0.56 is an effective benchmark for high-pressure superconductivity studies.

Detailed analysis of signal quality and transition temperatures across pressures.

Abstract

In recent years, the resistance signature of the high temperature superconductivity above 250 K in highly compressed hydrides (more than 100 GPa) has garnered significant attention within the condensed matter physics community. This has sparked renewed optimism for achieving superconductivity under room-temperature conditions. However, the superconducting diamagnetism, another crucial property for confirming the superconductivity, has yet to be conclusively observed. The primary challenge arises from the weak diamagnetic signals detected from the small samples compressed in diamond anvil cells. Therefore, the reported results of superconducting diamagnetism in hydrides have sparked intense debate, highlighting the urgent need for workable methodology to assess the validity of the experimental results. Here, we are the first to report the ultrahigh pressure measurements of the superconducting diamagnetism on Nb0.44Ti0.56, a commercial superconducting alloy, in a record-wide pressure range from 5 GPa to 160 GPa. We present detailed results on factors such as sample size, the diamagnetic signal intensity, the signal-to-noise ratio and the superconducting transition temperature across various pressures and different pressure transmitting media. These comprehensive results clearly demonstrate that this alloy is an ideal reference sample for evaluating superconductivity in compressed hydrides,validating the credibility of the experimental systems and superconducting diamagnetic results, as well as determining the nature of the superconductivity of the investigated sample. In addition, these results also provide a valuable benchmark for studying the pressure-induced superconductivity in other material families.