Medium-entropy Engineering of magnetism in layered antiferromagnet CuxNi2(1-x)CrxP2S6

TL;DR

This study investigates how medium-entropy alloying via Cu and Cr substitution in Ni2P2S6 influences its magnetic phases, revealing enhanced ferromagnetic correlations and potential for property tuning in layered antiferromagnets.

Contribution

It introduces a novel medium-entropy alloying approach to tune magnetism in layered antiferromagnetic compounds, expanding beyond traditional bimetallic substitution methods.

Findings

Systematic evolution of AFM phases with substitution.

Enhanced ferromagnetic correlations due to Cu and Cr doping.

Possible emergence of weak FM phase at low temperatures.

Abstract

Engineering magnetism in layered magnets could result in novel phenomena related to two-dimensional (2D) magnetism, which can be useful for fundamental research and practical applications. Extensive doping efforts such as substitution and intercalation have been adopted to tune antiferromagnetic (AFM) properties in M2P2X6 compounds. The substitutional doping in this material family has mainly focused on bimetallic substitution. Recently, the metal substitution can also be extended to more than two metal elements, leading to medium and high-entropy alloys (MEAs and HEAs), which are fairly underexplored in layered magnetic systems including M2P2X6. In this work, we explored the magnetic properties of the previously unreported Cu- and Cr-substituted Ni2P2S6 i.e., CuxNi2(1-x)CrxP2S6. Our study reveals a relatively systematic evolution of AFM phases with substitution than that observed in traditional bimetallic substitution in M2P2X6. Furthermore, the Cu and Cr substitutions in Ni2P2S6 are found to enhance the ferromagnetic (FM) correlation, which is also accompanied by a possible weak FM phase at low temperatures for the intermediate compositions from 0.32 to 0.80. Our work provides a strategy to establish ferromagnetism in AFM M2P2X6 that can also be used for property tuning in other layered magnets.