Study of the Stability of Structural Variants and Magnetic Properties of TmGa2.
Journal:
Inorganic chemistry
Published Date:
May 22, 2026
Abstract
We present a detailed study of the electronic structure, chemical bonding, and magnetic properties of TmGa2. The analysis of chemical pressure in a series of hexagonal REGa2 compounds (RE = La, Pr, Nd, Gd-Tm and Lu) reveals that steric factors contribute to the instability of the AlB2-type phase of TmGa2 and its transition to the orthorhombic KHg2-type crystal structure. Magnetic properties have been investigated in single crystals grown using a Pb flux. The temperature-dependent magnetic susceptibility measurements at different crystallographic orientations indicate an antiferromagnetic phase transition at TN = 3.5 K. In the low-temperature regime, magnetic susceptibility deviates from the Curie-Weiss law, showcasing a hump attributed to the crystalline electric field (CEF) effect. The CEF effect has been studied thoroughly based on a point charge model of an isostructural compound TmCu2, indicating the splitting of 13 nondegenerate levels in TmGa2. Isothermal magnetization along H∥c exhibits a metamagnetic transition at μ0Hc = 0.15 T. The overall magnetization remains low, with respect to the theoretical value for Tm3+, and does not reach saturation even at 9 T and 2 K. Temperature-dependent heat capacity data confirm the magnetic phase transition at TN and indicate the presence of the Schottky anomaly. The reduced value of magnetization, the jump in heat capacity, and the magnetic entropy at the magnetic ordering temperature, along with substantial magnetic anisotropy, suggest that CEF interaction plays a crucial role in determining the magnetic ground state in TmGa2. The nonmagnetic analogue LuGa2 has also been investigated down to 340 mK, but no superconducting transition has been detected. By employing density functional theory calculations, chemical bonding study, and machine learning-based chemical pressure analysis, we were able to explain the instability of the AlB2-type structure observed for two of the members of the REGa2 (RE = lanthanides and Y) series (TmGa2 and LuGa2) due to pressure-optimizing transition from the hexagonal AlB2-type structure.
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