Possible Pairing Symmetry of Three-dimensional Superconductor UPt3 -- Analysis Based on a Microscopic Calculation --

Abstract

Stimulated by the anomalous superconducting properties of UPt3, we investigate the pairing symmetry and the transition temperature in the two-dimensional(2D) and three-dimensional(3D) hexagonal Hubbard model. We solve the Eliashberg equation using the third order perturbation theory with respect to the on-site repulsion U. As results of the 2D calculation, we obtain distinct two types of stable spin-triplet pairing states. One is the f-wave(B1) pairing around n = 1.2 and in a small U region, which is caused by the ferromagnetic fluctuation. Then, the other is the px(or py)-wave(E1) pairing in large U region far from the half-filling (n = 1) which is caused by the vertex corrections only. However, we find that the former f-wave pairing is destroyed by introduced 3D dispersion. This is because the 3D dispersion breaks the favorable structures for the f-wave pairing such as the van Hove singularities and the small pocket structures. Thus, we conclude that the ferromagnetic fluctuation mediated spin-triplet state can not explain the superconductivity of UPt3. We also study the case of the pairing symmetry with a polar gap. This pz-wave(A1) is stabilized by the large hopping integral along c-axis tz. It is nearly degenerate with the suppressed px(or py)-wave(E1) in the best fitting parameter region to UPt3 (1.3 tz 1.5). These two p-wave pairing states exist in the region far from the half-filling, in which the vertex correction terms play crucial roles like the case in Sr2RuO4.

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