Quasiparticle spin susceptibility in heavy-fermion superconductors : An NMR study compared with specific heat results
Abstract
Quasi-particle spin susceptibility (qp) for various heavy-fermion (HF) superconductors are discussed on the basis of the experimental results of electronic specific heat (γel), NMR Knight shift (K) and NMR relaxation rate (1/T1) within the framework of the Fermi liquid model for a Kramers doublet crystal electric field (CEF) ground state. qpγ is calculated from the enhanced Sommerfeld coefficient γel and qpT1 from the quasi-particle Korringa relation T1T(KqpT1)2=const. via the relation of qpT1=(NAμB/Ahf)KqpT1 where Ahf is the hyperfine coupling constant, NA the Abogadoro's number and μB the Bohr magneton. For the even-parity (spin-singlet) superconductors CeCu2Si2, CeCoIn5 and UPd2Al3, the fractional decrease in the Knight shift, δ Kobs, below the superconducting transition temperature (Tc) is due to the decrease of the spin susceptibility of heavy quasi-particle estimated consistently from qpγ and qpT1. This result allows us to conclude that the heavy quasi-particles form the spin-singlet Cooper pairs in CeCu2Si2, CeCoIn5 and UPd2Al3. On the other hand, no reduction in the Knight shift is observed in UPt3 and UNi2Al3, nevertheless the estimated values of qpγ and qpT1 are large enough to be probed experimentally. The odd-parity superconductivity is therefore concluded in these compounds. The NMR result provides a convincing way to classify the HF superconductors into either even- or odd- parity paring together with the identification for the gap structure, as long as the system has Kramers degeneracy.
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