Crystal electric field excitations and spin dynamics in a spin-orbit coupled distorted honeycomb magnet BiErGeO5
Abstract
The magnetic properties and crystal electric field (CEF) scheme of BiErGeO5 are investigated via magnetization, heat capacity, muon spin relaxation (muSR), and inelastic neutron scattering (INS) experiments on a polycrystalline sample. The Er3+ ions form a quasi-two-dimensional distorted honeycomb network with a Kramers doublet ground state. Magnetic susceptibility and heat capacity reveal short-range antiferromagnetic correlations, manifested as a broad maximum around 1.4 K. Heat-capacity data further confirm the onset of a magnetic long-range order at T N = 0.4 K. The INS spectra exhibit eight CEF excitations and the CEF analysis yields the g-factor anisotropy with gxy/gz = 1.38 and exchange anisotropy with Jxy = 2.96 K and Jz = 1.56 K. The experimental temperature and field dependent magnetization and heat capacity are also reproduced by the simulation using CEF energy scheme. Zero-field muSR measurements down to 30 mK, do not exhibit coherent oscillations or a static 1/3 tail. The spectra are well described by two exponential relaxation components, indicating two magnetically inequivalent muon environments. The relaxation rates display a nearly temperature-independent plateau below T N and follow an Orbach-type activated behavior at higher temperatures involving excited CEF levels, consistent with the INS results. Longitudinal-field μSR measurements reveal only weak decoupling up to 1.5 T, indicating persistent slow spin fluctuations below T N.
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