Critical Current, Lengthwise Fluctuations, and Flux Jumps in REBCO CC: A Torque Magnetometry Study up to 45 T

TL;DR

This study develops a torque magnetometer to characterize REBCO coated conductors at magnetic fields up to 45 T, revealing critical current variations and flux jumps crucial for high-field applications.

Contribution

It introduces a simple, effective magnetometry method for assessing angular critical currents in REBCO tapes under extreme conditions, with detailed analysis of lengthwise fluctuations and flux jumps.

Findings

Significant lengthwise critical current variations near tape edges.

Flux jumps observed in thick REBCO layers with thin stabilizers.

REBCO tapes show strong performance potential in high magnetic fields.

Abstract

Rare Earth Barium Copper Oxide (REBCO) coated conductors (CCs) have emerged for future high field magnets in fields and temperatures inaccessible for Nb based superconductors. However, their exceptionally high current densities pose challenges for low temperature characterization. This paper presents the design and implementation of a simple torque magnetometer that is particularly suitable for characterizing REBCO CC. It details the construction and underlying physics, with a particular emphasis on its capability to assess the angular critical currents Ic in high magnetic fields and low temperatures. The study includes characterizations of multiple REBCO samples from different manufacturers, performed under magnetic fields up to 45 T, demonstrating the exceptional capabilities of REBCO CCs in extreme fields. The results revealed significant lengthwise Ic variations, especially in tapes cut from the edges of 12 mm-wide production tapes compared to those cut from the center. These variations are most pronounced when the field is near the ab plane. Importantly, flux jumps are observed in samples with thick REBCO layers and thin stabilizers, underscoring the potential thermal instabilities. These findings provide valuable insights into the performance of REBCO tapes under extreme magnetic fields, highlighting their relevance for high-field magnet and nuclear fusion applications.