Role of crystal field ground state in the classical spin-liquid behavior of a quasi-one dimensional spin-chain system Sr3NiPtO6

Abstract

The spin-chain compound Sr3NiPtO6 is known to have a nonmagnetic ground state. We have investigated the nature of ground state of Sr3NiPtO6 using magnetic susceptibility (T), heat capacity C p(T), muon spin relaxation (μSR) and inelastic neutron scattering (INS) measurements. The (T) and C p(T) do not exhibit any pronounced anomaly that can be associated with a phase transition to a magnetically ordered state. Our μSR data confirm the absence of long-range magnetic ordering down to 0.04 K. Furthermore, the muon spin relaxation rate increases below 20 K and exhibits temperature independent behavior at low temperature, very similar to that observed in a quantum spin-liquid system. The INS data show a large excitation near 8~meV, and the analysis of the INS data reveals a singlet CEF ground state with a first excited CEF doublet state at CEF = 7.7 meV. The estimated CEF parameters reveal a strong planar anisotropy in the calculated (T), consistent with the reported behavior of the (T) of single crystal Sr3NiPtO6. We propose that the nonmagnetic singlet ground state and a large CEF (much larger than the exchange interaction J ex) are responsible for the absence of long-range magnetic ordering and can mimic a classical spin-liquid behavior in this quasi-1D spin chain system Sr3NiPtO6. The classical spin-liquid ground state observed in Sr3NiPtO6 is due to the single-ion property, which is different from the quantum spin-liquid ground state observed in geometrically frustrated systems, where two-ion exchanges play an important role.

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