Determining the phase diagram of atomically thin layered antiferromagnet CrCl3

Abstract

Changes in the spin configuration of atomically-thin, magnetic van-der-Waals multilayers can cause drastic modifications in their opto-electronic properties. Conversely, the opto-electronic response of these systems provides information about the magnetic state, very difficult to obtain otherwise. Here we show that in CrCl3 multilayers, the dependence of the tunnelling conductance on applied magnetic field (H), temperature (T), and number of layers (N) tracks the evolution of the magnetic state, enabling the magnetic phase diagram of these systems to be determined experimentally. Besides a high-field spin-flip transition occurring for all thicknesses, the in-plane magnetoconductance exhibits an even-odd effect due to a low-field spin-flop transition. If the layer number N is even, the transition occurs at μ0 H 0 T due to the very small in-plane magnetic anisotropy, whereas for odd N the net magnetization of the uncompensated layer causes the transition to occur at finite H. Through a quantitative analysis of the phenomena, we determine the interlayer exchange coupling as well as the staggered magnetization, and show that in CrCl3 shape anisotropy dominates. Our results reveal the rich behaviour of atomically-thin layered antiferromagnets with weak magnetic anisotropy.