6533b7d5fe1ef96bd1265049

RESEARCH PRODUCT

Magnetic-field-induced reentrance of Fermi-liquid behavior and spin-lattice relaxation rates in

Alfred Z. MsezaneVasily R. ShaginyanVasily R. ShaginyanKonstantin G. PopovVladimir A. Stephanovich

subject

Quantum phase transitionPhysicsMagnetoresistanceCondensed matter physicsSpin–lattice relaxationGeneral Physics and Astronomy01 natural sciencesMagnetic susceptibility010305 fluids & plasmasEffective mass (solid-state physics)0103 physical sciencesQuasiparticleStrongly correlated materialFermi liquid theory010306 general physics

description

Abstract A strong departure from Landau–Fermi liquid (LFL) behavior have been recently revealed in observed anomalies in both the magnetic susceptibility χ and the muon and 63Cu nuclear spin-lattice relaxation rates 1 / T 1 of YbCu 5 − x Au x ( x = 0.6 ). We show that the above anomalies along with magnetic-field-induced reentrance of LFL properties are indeed determined by the dependence of the quasiparticle effective mass M ∗ on magnetic field B and temperature T and demonstrate that violations of the Korringa law also come from M ∗ ( B , T ) dependence. We obtain this dependence theoretically utilizing our approach based on fermion condensation quantum phase transition (FCQPT) notion. Our theoretical analysis of experimental data on the base of FCQPT approach permits not only to explain the above two experimental facts in a unified manner, but to unveil their universal properties, relating the peculiar features of both longitudinal magnetoresistance and specific heat in YbRh2Si2 to the behavior of spin-lattice relaxation rates.

yearjournalcountryeditionlanguage
2009-10-01Physics Letters A
https://doi.org/10.1016/j.physleta.2009.08.011