Absence of Long-Range Order and Magnetic Anisotropy in the Triangular Magnet NdMgAl11O19

Abstract

We investigated the rare-earth triangular-lattice antiferromagnet NdMgAl11O19 using single-crystal magnetization (1.8~K ≤ T ≤ 300~K, μ0 H ≤ 7~T) and specific-heat measurements down to 45~mK. The dc susceptibility confirms a well-isolated Kramers doublet ground state with pronounced Ising-type anisotropy, with gc ≈ 3.7 and gab ≈ 1.45. Curie--Weiss fits yield weak, anisotropic antiferromagnetic exchange, with θc = -0.54~K and θab = -0.87~K. Heat-capacity measurements show no long-range magnetic order down to 40~mK, corresponding to a frustration index f 20. Instead, Cm/T exhibits a broad maximum near 0.081~K whose magnitude and field evolution are consistent with short-range correlations in an anisotropic triangular lattice. Applied magnetic fields open a Zeeman gap where the specific-heat anomaly follows = g μB μ0 H, and M(H,T) is well described by a Brillouin function for an effective J = 1/2 moment. The field tuning of the low-temperature entropy manifold allows self-cooling from 1.8~K to 53~mK by adiabatic demagnetisation from a 9~T field. These results identify NdMgAl11O19 as a nearly ideal weak-exchange triangular magnet with a field-tunable correlated ground state, where two-dimensional crossover effects may emerge from frustrated XXZ interactions.