Field-induced compensation of magnetic exchange as the possible origin of reentrant superconductivity in UTe$_2$

TL;DR

This study investigates the reentrant superconductivity in UTe$_2$ under high magnetic fields, revealing a possible mechanism involving field-induced exchange compensation that sustains superconductivity beyond typical limits.

Contribution

It provides experimental evidence linking magnetic exchange compensation to reentrant superconductivity in UTe$_2$, highlighting the Jaccarino-Peter effect as a key mechanism.

Findings

Record upper critical field of ~73 T in UTe$_2$

Suppression of Hall effect indicating reduced band polarization

Angular dependence of superconductivity related to exchange field compensation

Abstract

The potential spin-triplet heavy-fermion superconductor UTe$_2$ exhibits signatures of multiple distinct superconducting phases. For field aligned along the $b$ axis, a metamagnetic transition occurs at $\mu_0 H_\mathrm{m}\approx35\,$T. It is associated with magnetic fluctuations that may be beneficial for the field-reinforced superconductivity surviving up to $H_\mathrm{m}$. Once the field is tilted away from the $b$ towards the $c$ axis, a reentrant superconducting phase emerges just above $H_\mathrm{m}$. In order to better understand this remarkably field-resistant superconducting phase, we conducted magnetic-torque and magnetotransport measurements in pulsed magnetic fields. We determine the record-breaking upper critical field of $\mu_0 H_\mathrm{c2}\approx 73\,$T and its evolution with angle. Furthermore, the normal-state Hall effect experiences a drastic suppression indicative of a reduced band polarization above $H_\mathrm{m}$ in the angular range around $30^\circ$ caused by a partial compensation between the applied field and an exchange field. This promotes the Jaccarino-Peter effect as a likely mechanism for the reentrant superconductivity above $H_\mathrm{m}$.