Sharp magnetization jump at the first-order superconducting transition in Sr2RuO4

TL;DR

This study reveals a sharp first-order superconducting transition in Sr2RuO4 characterized by a magnetization jump and high anisotropy, challenging existing theories about its superconducting state.

Contribution

The paper provides direct experimental evidence of a first-order transition and intrinsic anisotropy in Sr2RuO4, offering new insights into its superconducting properties.

Findings

Observation of a sharp magnetization jump at Hc2

Confirmation of a large intrinsic anisotropy (Γ=60)

Evidence of a first-order superconducting-normal transition

Abstract

The magnetization and magnetic torque of a high-quality single crystal of Sr$_2$RuO$_4$ have been measured down to 0.1 K under a precise control of the magnetic-field orientation. When the magnetic field is applied exactly parallel to the $ab$ plane, a sharp magnetization jump $4\pi\delta M$ of $(0.74 \pm 0.15)$ G at the upper critical field $H_{{\rm c2},{ab}} \sim 15$ kOe with a field hysteresis of 100 Oe is observed at low temperatures, evidencing a first-order superconducting-normal transition. A strong magnetic torque appearing when $H$ is slightly tilted away from the $ab$ plane confirms an intrinsic anisotropy $\varGamma=\xi_a/\xi_c$ of as large as 60 even at 100 mK, in contrast with the observed $H_{{\rm c2}}$ anisotropy of $\sim 20$. The present results raise fundamental issues in both the existing spin-triplet and spin-singlet scenarios, providing, in turn, crucial hints toward the resolution of the superconducting nature of Sr$_2$RuO$_4$.