Controlling Magnetism in the 2D van der Waals Antiferromagnet CrPS4 via Ion Intercalation

Abstract

Two-dimensional van der Waals (vdW) magnetic materials are versatile platforms for tailoring electronic and magnetic properties, in which the insertion of chemical species into their interlayer gaps offers a powerful route to engineer magnetism. Here, we focus on the A-type antiferromagnetic semiconductor CrPS4 (TN = 38 K) and investigate its electronic and magnetic properties upon intercalation of lithium (Li+) and organic tetrabutylammonium (TBA+) ions using first-principles calculations. Our results show that Li+ incorporation induces a semiconductor-to-metal transition in CrPS4 and selectively modifies its magnetic behaviour: switching from out-of-plane to in-plane antiferromagnetism, followed by an in-plane ferromagnetic ground state at higher intercalation levels. This is accompanied by a continuous increase of the ordering temperature, reaching a fivefold enhancement for Li0.5CrPS4. Similarly, TBA+ intercalation expands the vdW gap, decoupling CrPS4 layers and stabilising in-plane ferromagnetism with a TC above 100 K. Furthermore, it also modifies magnon propagation, leading to enhanced group velocities and a more isotropic magnon transport. This work highlights intercalation as a powerful and versatile approach for controlling magnetic behaviour and spin dynamics, paving the way for the design of tunable 2D layered magnetic materials for spintronic and magnonic applications.

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