Dynamical magnetism in the disordered cubic lattice material γ- Ba3 CoNb2 O9

Abstract

γ- Ba3 CoNb2 O9 realizes a disordered simple-cubic spin-1/2 lattice in which Co2+ ions randomly occupy one third of the sites, placing the system close to the site-percolation threshold for magnetic order. Specific-heat, susceptibility, neutron spin-echo, and muon spin-rotation measurements reveal a broad thermodynamic crossover, short-range magnetic correlations, and persistent fast spin dynamics down to at least 0.1~K, with no evidence for static order or conventional spin-glass freezing. Monte Carlo simulations yield a broad distribution of orphan spins, finite clusters, and an infinite network. The calculated orphan-spin fraction (≈ 8.8\%) agrees well with the weakly correlated spin fraction inferred from magnetization (≈ 8.2\%). Exact diagonalization of a diluted S = 1/2 Heisenberg model captures the broad magnetic specific-heat anomaly and supports the coexistence of weakly and strongly correlated spin environments. These results support a picture in which spin-1/2 quantum fluctuations, together with dilution and proximity to the percolation threshold, can support a disorder-driven dynamical state with short-range correlations in three dimensions, distinct from both classical spin glasses and geometrically frustrated quantum spin liquids.