Stripe antiferromagnetism in van der Waals metal HoTe3 decoupled from charge density wave order

Abstract

The RTe3 (R = rare earth) family of layered van der Waals (vdW) compounds hosts coexisting magnetic and charge density wave (CDW) orders, yet the interplay between these degrees of freedom remains little explored. Combining polarized and unpolarized neutron diffraction on single-crystal HoTe3, we identify two distinct antiferromagnetic (AFM) phases, both exhibiting a collinear motif within individual vdW layers. The two phases are distinguished by the vdW stacking of magnetic layers: ferromagnetic (FM) stacking in the higher-temperature AFM-II phase, here termed ``vertical-stripe'', and AFM stacking in the AFM-I ground state, here termed ``tilted-stripe''; the two phases have propagation vectors qm2 = (0.48, 0, 0) and qm1 = (0.5, 0.5, 0), respectively. In contrast to the CDW-driven exotic magnetism in DyTe3, TbTe3, and GdTe3, we find no evidence for coupling between magnetism and CDW in HoTe3. The relative alignment between AFM and CDW propagation vectors, as well as single-ion anisotropy, are likely essential for generating coupled spin/charge orders in layered vdW systems.