High-temperature magnetization and entropy of the triangular lattice Hubbard model in a Zeeman field

Abstract

We use strong coupling expansions to calculate the entropy function S(T,h), the magnetization M(T,h), and the double occupancy factor D(T,h) for the half-filled triangular lattice Hubbard model as a function of temperature T and Zeeman field h, for various values of the Hubbard parameter ratio U/t. These calculations converge well for temperatures larger than the exchange parameter J=4t2U for moderate to large U/t values. Setting μ=U/2 suffices to obtain the density of half filling within a fraction of one percent at all temperatures studied for U/t ≥ 8. We discuss the systematic variation of properties with U/t. The temperature dependence of entropy and the double occupancy parameter shows a mapping to an antiferromagnetic Mott insulating behavior at temperatures well above T=J for U/t 10. Convergence of the series is weaker at intermediate fields implying non-monotonic variation of spin-correlations with the Zeeman field. We discuss the relevance of the Hubbard model results to the triangular-lattice antiferromagnetic materials Lu3Cu2Sb3O14 (LCSO) studied recently by Yang et al [Yang et al arXiv:2102.09271 (2022)].