Quantum Griffiths phase in the kagome Kondo lattice CeRh0.9Pd0.1Sn

Abstract

CeRhSn is a valence fluctuating heavy-fermion metal with a twisted Ce-kagome lattice, displaying zero-field quantum criticality, previously associated with geometrical frustration. The partial substitution of Rh by Pd in CeRh1-xPdxSn enlarges the unit-cell volume, suppresses valence fluctuations, decreases the Kondo temperature and stabilizes a possible long-range antiferromagnetic (AFM) ordered ground state with TN=0.8 K at x=0.5. Previous thermodynamic and spectroscopic measurements for x=0.1 suggested a quantum critical spin liquid. We report low-temperature dilatometry and magnetization measurements on CeRh0.9Pd0.1Sn and compare with published low-T specific heat data. The absence of a Gr\"uneisen parameter divergence excludes a conventional quantum criticality scenario. Instead, the weak power-law divergences signal non-Fermi liquid (NFL) behavior, according to a disorder-driven quantum Griffiths phase scenario. At low temperatures, a negative thermal expansion is found in fields above approximately 0.5 T and the NFL scaling breaks down, probably due to the polarization of AFM correlations.