Dynamic Spin Fluctuations in the Frustrated Spin Chain Compound Li3Cu2SbO6

Abstract

We report the signatures of dynamic spin fluctuations in the layered honeycomb Li3Cu2SbO6 compound, with a 3d S = 1/2 d9 Cu2+ configuration, through muon spin rotation and relaxation (μSR) and neutron scattering studies. Our zero-field (ZF) and longitudinal-field (LF)-μSR results demonstrate the slowing down of the Cu2+ spin fluctuations below 4.0 K. The saturation of the ZF relaxation rate at low temperature, together with its weak dependence on the longitudinal field between 0 and 3.2 kG, indicates the presence of dynamic spin fluctuations persisting even at 80 mK without static order. Neutron scattering study reveals the gaped magnetic excitations with three modes at 7.7, 13.5 and 33 meV. Our DFT calculations reveal that the next nearest neighbors (NNN) AFM exchange (JAFM = 31 meV) is stronger than the NN FM exchange (JFM = -21 meV) indicating the importance of the orbital degrees of freedom. Our results suggest that the physics of Li3Cu2SbO6 can be explained by an alternating AFM chain rather than the honeycomb lattice.