Quantum Criticality in doped CePd1-xRhx Ferromagnet
Abstract
CePd1-xRhx alloys exhibit a continuous evolution from ferromagnetism (TC= 6.5 K) at x = 0 to a mixed valence (MV) state at x = 1. We have performed a detailed investigation on the suppression of the ferromagnetic (F) phase in this alloy using dc-(dc) and ac-susceptibility (ac), specific heat (Cm), resistivity () and thermal expansion (β) techniques. Our results show a continuous decrease of TC (x) with negative curvature down to TC = 3K at x*= 0.65, where a positive curvature takes over. Beyond x*, a cusp in cac is traced down to TC* = 25 mK at x = 0.87, locating the critical concentration between x = 0.87 and 0.90. The quantum criticality of this region is recognized by the -log(T/T0) dependence of Cm/T, which transforms into a T-q (~0.5) one at x = 0.87. At high temperature, this system shows the onset of valence instability revealed by a deviation from Vegard's law (at xV~0.75) and increasing hybridization effects on high temperature dc and . Coincidentally, a Fermi liquid contribution to the specific heat arises from the MV component, which becomes dominant at the CeRh limit. In contrast to antiferromagnetic systems, no Cm/T flattening is observed for x > xcr rather the mentioned power law divergence, which coincides with a change of sign of β. The coexistence of F and MV components and the sudden changes in the T dependencies are discussed in the context of randomly distributed magnetic and Kondo couplings.
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