Strong-coupling theory of magnetic-exciton-mediated superconductivity in UPd2Al3
Abstract
There is compelling evidence from inelastic-neutron-scattering and tunneling experiments that the heavy-fermion superconductor UPd2Al3 can be understood as a dual system consisting of magnetic excitons, arising from crystal-field-split U4+ levels, coupled to delocalised f-electrons. We have computed the superconducting transition temperature and the mass renormalisation arising from a dual model with maximal spin anisotropy using a strong-coupling approach. We find an instability to two possible opposite-spin-pairing states with even- or odd-parity gap functions. Each has a line node perpendicular to the c-direction, in agreement with NMR relaxation-rate, specific-heat and thermal-conductivity measurements. In addition, both have total spin component Sz=0, compatible with the observation of a pronounced Knight shift and Hc2 Pauli limiting. For parameter values appropriate to UPd2Al3, we determine the dependence of the superconducting transition temperature Tc on a phenomenological coupling constant g and we investigate the associated mass enhancement and its anisotropy.
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