Realization of the Ruby Lattice Antiferromagnet in Layered Transition-Metal Fluorides

Abstract

The antiferromagnet on the ruby lattice is expected to host a range of exotic emergent phenomena, yet its material realization has remained elusive. Here we show that the layered transition metal fluorides CsBaFe3F12 and CsBaCr3F12 with Fe3+ and Cr3+ ions realize only slightly distorted ruby lattice geometries with spin moments S=5/2 and S=3/2, respectively. Their microscopic Hamiltonians, calculated with DFT energy mapping, are dominated by short-ranged antiferromagnetic interactions within the ruby layers. Classical Monte Carlo simulations reveal strong frustration in both compounds, with local Néel correlations on the hexagonal plaquettes and distinct long-range ordering tendencies governed by weaker triangular links. For CsBaFe3F12, the calculated thermodynamic behaviour is consistent with the experimentally reported magnetic ordering scale. For CsBaCr3F12, classical Monte Carlo and Luttinger-Tisza analysis reveal competing low-energy ordering wave vectors, strong finite-size sensitivity, and a tendency toward incommensurate order. Overall, our results establish these fluorides as experimentally accessible ruby-lattice antiferromagnets and provide quantitative predictions for future neutron-scattering studies.