Anisotropic large magnetoresistance and Fermi surface topology of terbium monoantimonide

Rare-earth monopnictides have received a great deal of attention for their exotic magnetic and electronic properties. Here, we grow high-quality TbSb single crystals, and perform their magnetization, specific heat and transport measurements, and band structure calculations. In this compound, an antiferromagnetic phase transition emerges at ~14.5 K (TN), below which metamagnetic behaviors can be observed. Specific heat data suggest that G4 triplet state dominates the ground magnetic properties, and thus gives rise to weak magnetic anisotropy. Analogous to other isostructural counterparts, TbSb shows extreme magnetoresistance and triangular temperature-field phase diagram. Hall resistivity measurements reveal that carrier concentrations and mobilities change their values in different magnetic states. These findings are supported by the theoretical calculations from which the effect of magnetic orderings on Fermi surface topology can be determined. Nevertheless, the magnetoresistance below and above TN in TbSb shares similar angle dependences, and follows the fashions as observed in those nonmagnetic sister compounds because of its weak anisotropy in magnetization. Our studies uncover the spin ordering effects on angular magnetoresistance and electronic band structures of TbSb, and could be employed to understand the related issues in other systems with similar magnetic behaviors. (c) 2022 Elsevier Ltd. All rights reserved.

Automated summary

Rare-earth monopnictides, including TbSb, have attracted attention due to their exotic magnetic and electronic properties. In this study, high-quality TbSb single crystals were grown and their magnetic properties, such as antiferromagnetic phase transition and metamagnetic behaviors, were investigated. The specific heat data suggest a dominant G4 triplet state and weak magnetic anisotropy. TbSb exhibits extreme magnetoresistance and triangular temperature-field phase diagram, and the Hall resistivity measurements show varying carrier concentrations and mobilities in different magnetic states. The findings contribute to understanding the effects of spin ordering on angular magnetoresistance and electronic band structures in TbSb and related systems.