Field-Induced Magnetic States in the Metallic Rare-Earth Layered Triangular Antiferromagnet TbAuAl4Ge2

Abstract

Magnetic frustration in metallic rare earth lanthanides (Ln) with 4f-electrons is crucial for producing interesting magnetic phases with high magnetic anisotropy where intertwined charge and spin degrees of freedom lead to novel phenomena. Here we report on the magnetic, thermodynamic, and electrical transport properties of TbAuAl4Ge2. Tb ions form 2-dimensional triangular lattice layers which stack along the crystalline c-axis. The magnetic phase diagram reveals multiple nearly degenerate ordered states upon applying field along the magnetically easy ab-plane before saturation. The magnetoresistance in this configuration exhibits intricate field dependence that closely follows that of the magnetization while the specific heat reveals a region of highly enhanced entropy, suggesting the possibility of a non-trivial spin textured phase. For fields applied along the c-axis (hard axis), we find linear magnetoresistance over a wide range of fields. We compare the magnetic properties and magnetoresistance with an isostructral GdAuAl4Ge2 single crystals. These results identify TbAuAl4Ge2 as an environment for complex quantum spin states and pave the way for further investigations of the broader LnAuAl4Ge2 family of materials.