Studying Critical Parameters of Superconductor via Diamond Quantum Sensors

TL;DR

This paper demonstrates how nitrogen-vacancy (NV) diamond sensors can non-invasively measure multiple critical parameters of superconductors, such as critical fields and current density, using a single sensor platform.

Contribution

The study introduces a novel application of NV diamond sensors to simultaneously determine various critical parameters of superconductors, streamlining the measurement process.

Findings

Successfully measured critical fields and current density in YBCO superconductor.

Verified the unconventional nature of high-temperature superconductor YBCO.

Demonstrated non-invasive, stable sensing of magnetic properties using diamond NV centers.

Abstract

Critical parameters are the key to superconductivity research, and reliable instrumentations can facilitate the study. Traditionally, one has to use several different measurement techniques to measure critical parameters separately. In this work, we develop the use of a single species of quantum sensor to determine and estimate several critical parameters with the help of independent simulation data. We utilize the nitrogen-vacancy (NV) center in the diamond, which recently emerged as a promising candidate for probing exotic features in condensed matter physics. The non-invasive and highly stable nature provides extraordinary opportunities to solve scientific problems in various systems. Using a high-quality single-crystalline YBa$_{2}$Cu$_{4}$O$_{8}$ (YBCO) as a platform, we demonstrate the use of diamond particles and a bulk diamond to probe the Meissner effect. The evolution of the vector magnetic field, the $H-T$ phase diagram, and the map of fluorescence contour are studied via NV sensing. Our results reveal different critical parameters, including lower critical field $H_{c1}$, upper critical field $H_{c2}$, and critical current density $j_{c}$, as well as verifying the unconventional nature of this high-temperature superconductor YBCO. Therefore, NV-based quantum sensing techniques have huge potential in condensed matter research.