Emergent Dynamic Magnetic Ground State in a Mixed 3d/5d Heavy Fermion System CaCu3Ir4O12

Abstract

Quantum-disordered magnetic ground states are challenging to identify in three-dimensional (3D) oxides, where strong exchange pathways typically favour long-range magnetic order or spin freezing. The quadruple perovskite CaCu3Ir4O12, crystallizing in the cubic Im3 structure, provides a 3D lattice where Cu2+ 3d moments are coupled to an extended Ir 5d network, offering a rare platform for probing quantum-disordered magnetism in a mixed 3d/5d electron system. Here, we combine bulk probes, including DC and AC magnetic susceptibility, and heat capacity measurements (down to 50~mK), along with the local microscopic probe muon spin relaxation (μSR) (down to 40~mK), to investigate the true magnetic ground state of CaCu3Ir4O12. Despite strong antiferromagnetic interactions (θW -200~K, with an applied-field dependence), no signature of long-range magnetic ordering or spin freezing is detected down to the lowest measured temperatures. Furthermore, our in-depth zero-field (ZF) and longitudinal-field (LF) μSR characterizations confirm strong quantum spin fluctuations and the truly dynamic nature of the local moments down to 40~mK. These results establish CaCu3Ir4O12 as a promising 3D quantum-disordered magnet and a well-characterized platform for exploring fluctuation-dominated states in correlated 3d/5d oxides.