Magnetic field induced spin-flop transition in Na$_x$CoO$_2$ (0.5$<$x$<$0.55)

TL;DR

This study reveals a magnetic field-induced spin-flop transition in Na$_{0.52}$CoO$_2$, showing different magnetoresistance behaviors depending on field orientation, which suggests complex magnetism linked to potential superconductivity.

Contribution

It provides experimental evidence for a spin-flop transition in Na$_x$CoO$_2$ with field orientation, highlighting complex magnetic phenomena near the superconducting phase.

Findings

H $ot$ ab plane causes positive MR at low temperature

H $ot$ ab plane exhibits hysteresis below 25 K

Spin-flop transition induces metamagnetic behavior

Abstract

The isothermal magnetoresistance (MR) with magnetic field (H) parallel to and perpendicular to ab plane is systematically studied on the single crystal Na$_{0.52}$CoO$_2$ with charge ordering at $\sim 50$ K and an in-plane ferromagnetism below 25 K. The isothermal MR behavior with H $\parallel$ ab plane and H $\perp$ ab plane is quite different. When H $\parallel$ ab plane, the MR is always negative and the in-plane ferromagnetic behavior is enhanced. While the MR with H $\perp$ ab plane changes from negative to positive with decreasing temperature or increasing H, and the in-plane ferromagnetic behavior is suppressed. A striking feature is that the MR with H $\perp$ ab plane shows a hysteresis behavior below 25 K, which is absent for the case of H $\parallel$ ab plane. These results provide strong evidence for a spin-flop transition of small moments of Co$^{3.5-\delta}$ sites induced by H $\perp$ ab plane, leading to a metamagnetic transition for small moments of Co$^{3.5-\delta}$ sites. These complex magnetism suggests an unconventional superconductivity in Na$_x$CoO$_2$ system because the Na$_x$CoO$_2$ around x=0.5 is considered to be the parent compound of superconductivity.