Intrinsic thermodynamic properties of the pyrochlore superconductor RbOs2O6 extracted by condensation energy analysis
Abstract
We develop a general procedure for the analysis of bulk thermodynamic data of a superconductor for samples containing a metallic non-superconducting second phase. The method is based on the condensation energy and it allows the extraction of the intrinsic properties of a superconductor even for non-ideal samples. Applying this procedure to the recently discovered geometrically frustrated beta-pyrochlore superconductor RbOs2O6 (Tc = 6.4 K) yields a Sommerfeld coefficient as high as 79 mu J/g/K2 (44 mJ/molf.u./K2). RbOs2O6 is inferred to be a strong type-II superconductor (kappa(Tc) = 23) in the intermediate-coupling regime similar to niobium (lambdaep ≈ 1). From the upper critical field mu0 Hc2 ≈ 6 T at 0 K, we estimate a Ginzburg-Landau coherence length xi ≈ 74 AA. The condensation energy is 860 mu J/g (483 mJ/molf.u.) resulting in 1/(8 pi) (gamma1 Tc2)/DeltaU1 ≈ 0.15, a value well in the range of conventional phonon-mediated superconductors. The superconducting electronic specific heat indicates conventional s-wave pairing. The experimental Sommerfeld coefficient of 44 mJ/molf.u./K2 is about 4 times larger than the one found in band structure calculations. Together with the electron-phonon coupling constant lambdaep ≈ 1 this leaves an additional lambdaadd ≈ 2.4 for enhancement due to other mechanisms.
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