Linear Magnetoresistance and Anomalous Hall Effect in the Superconductor NiBi$_{3}$

TL;DR

This study reveals unconventional magnetic phenomena and complex magnetotransport behavior in NiBi3, highlighting the interplay of superconductivity, magnetism, and topological effects in this compound.

Contribution

It provides experimental evidence of magnetic fluctuations and anomalous Hall effect in NiBi3, emphasizing the material's intertwined magnetic and topological electronic structure.

Findings

Magnetoresistance shows non-standard temperature dependence.

Anomalous Hall effect persists down to superconducting transition.

Magnetic fluctuations influence charge transport.

Abstract

The NiBi$_{3}$ compound exhibits a compelling interplay between superconductivity and magnetism, further enriched by topological characteristics that make it an exceptional platform for exploring emergent electronic phenomena. Here, we report experimental evidence of unconventional magnetic phenomena in high-quality single crystals of NiBi$_3$, revealed through detailed magnetotransport measurements. The magnetoresistance displays a non-usual temperature dependence, featuring both a classical Lorentz-like component and a linear-in-field contribution. In addition, anomalous Hall effect signal persist down to the superconducting transition temperature and vanish above 75 K. These observations suggest that magnetic fluctuations play a significant role in charge transport in NiBi$_{3}$, highlighting a magnetically and topologically intertwined electronic structure. Our findings underscore the complex and multifaceted nature of this material.