Disorder-driven coexistence of distinct dynamical states in frustrated Sr3CuNb2O9: a microscopic μSR and 93Nb NMR study

Abstract

Despite recent progress in identifying the exotic random singlet (RS) state in disordered frustrated magnets as a distinct correlated phase, three-dimensional (3D) realizations remain scarce. Sr3CuNb2O9 was proposed to be one of such 3D frustrated systems with magnetic site disorder hosting an RS ground state. Here, we report a detailed microscopic investigation of Sr3CuNb2O9 employing muon spin relaxation (μSR) and 93Nb nuclear magnetic resonance (NMR) techniques. The μSR zero-field relaxation rate reveals a power-law divergence of the relaxation rate as a function of temperature. Also, a power-law divergence is present in the relaxation rate as a function of applied longitudinal field, consistent with the formation of an RS phase. The 93Nb NMR spectra unambiguously resolve two components with distinct local magnetic environments, whose nature is further elucidated through spin-lattice relaxation measurements analyzed via an inverse Laplace transform (ILT) of the nuclear magnetization recovery. The relaxation-rate distribution obtained from ILT reveals two well-separated channels: a fast component, (1/T1)fast, and a slow component, (1/T1)slow. Both components follow distinct power-law temperature dependences (Tα), with α = 0.6 and 1.1 for the fast and slow channels, respectively. The combined spectral and relaxation data demonstrate that the fast channel qualitatively represents an RS-like state, whereas the slow channel exhibits quantum spin liquid (QSL) like behavior, thereby establishing the microscopic coexistence of RS and QSL-like phases in Sr3CuNb2O9.