Quantum Griffiths singularity in the stoichiometric heavy-fermion system CeRh4Al15

Abstract

We present a detailed investigation of the stoichiometric CeRh4Al15 single crystal compound using the temperature dependence of the heat capacity [CP(T)], electrical resistivity [(T)], magnetic susceptibility [(T)], and magnetization [M(H)] measurements for a magnetic field (H) applied in the basal plane and along the c-axis. The low temperature power-law behavior of C/T T-1+α, the isotherm magnetization, M Hα with the exponent α = 0.45 - 0.55, and the T-linear resistivity Tε with ε 1 are found to be consistent with the formation of quantum Griffiths singularities in the non-Fermi-liquid (NFL) regime. We further investigated the spin dynamics of a polycrystalline sample of CeRh4Al15, using zero-field (ZF) and longitudinal-field (LF) muon spin relaxation (μSR) measurements. ZF-μSR measurements do not reveal any sign of long-range magnetic ordering down to 70~mK. The electronic relaxation rate (λ) below 0.5~K increases rapidly and shows a thermal activation-like characteristic [Tlog(λ) T] over the entire measured temperature range between 70~mK to 4~K, indicating the presence of low energy spin fluctuations in CeRh4Al15. LF-μSR measurements show a time-field (t/Hη) scaling of the μSR asymmetry indicating a quantum critical behavior of this compound. Furthermore, inelastic neutron scattering study on the polycrystalline sample reveals two crystal field excitations near 19 and 33~meV. These features collectively provide strong evidence of NFL behavior in CeRh4Al15 due to the formation of Griffiths phase close to a T → 0~K quantum critical point.