Chalcogen Doping Effect on the Insulator-to-Metal Transition in GdPS

TL;DR

This study explores how selenium doping affects the insulator-to-metal transition and magnetic properties of GdPS, revealing that increased spin-orbit coupling suppresses the transition and alters magnetic anisotropy.

Contribution

It provides new insights into the role of chalcogen doping in tuning the electronic and magnetic properties of GdPS, a topological semimetal with potential applications.

Findings

Se substitution slightly increases magnetic anisotropy.

Se doping suppresses the insulator-to-metal transition.

Enlarged band gap requires higher exchange splitting.

Abstract

Topological semimetals offer a rich platform for exploring massless fermion physics and realizing exotic properties with potential technological applications. GdPS, a magnetic semiconductor derived from the nodal-line semimetal ZrSiS family, exhibits a field-induced insulator-to-metal transition driven by exchange splitting. This transition is accompanied by an unusual, isotropic, and gigantic negative magnetoresistance, attributed to negligible magnetic anisotropy resulting from the weak spin-orbit coupling of half-filled Gd3+ 4f orbitals and light S atoms. In this work, we investigate Se substitution, which is expected to enhance spin-orbit coupling. Indeed, we observe slightly increased magnetic anisotropy in magnetotransport. Moreover, Se substitution suppresses the field-induced insulator-to-metal transition, likely due to an enlarged band gap that demands a higher exchange splitting to close. These findings provide deeper insights into the interplay between spin-orbit coupling, magnetic anisotropy, and transport behavior in GdPS, offering guidance for future materials design for desired functionalities.