Relationship between resistivity and specific heat in a canonical non-magnetic heavy fermion alloy system: UPt5-xAux
Abstract
UPt(5-x)Aux alloys form in a single crystal structure, cubic AuBe5-type, over a wide range of concentrations from x = 0 to at least x = 2.5. All investigated alloys, with an exception for x = 2.5, were non-magnetic. Their electronic specific heat coefficient γ varies from about 60 (x = 2) to about 700 mJ/mol K2 (x = 1). The electrical resistivity for all alloys has a Fermi-liquid-like temperature variation, = o + AT2, in the limit of T -> 0 K. The coefficient A is strongly enhanced in the heavy-fermion regime in comparison with normal and transition metals. It changes from about 0.01 (x = 0) to over 2 micro-ohm cm/K2 (x = 1). A/γ2, which has been postulated to have a universal value for heavy-fermions, varies from about 10-6 (x = 0, 0.5) to 10-5 micro-ohm cm (mol K/mJ)2 (x > 1.1), thus from a value typical of transition metals to that found for some other heavy-fermion metals. This ratio is unaffected, or only weakly affected, by chemical or crystallographic disorder. It correlates with the paramagnetic Curie-Weiss temperature of the high temperature magnetic susceptibility.
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