Superconductivity in NaxCoO2·yH2O : Is Spin-Charge Separation Protecting a d1+id2 State ?
Abstract
Superconductivity in NaxCoO2·yH2O is likely to be a p or d-wave; however, experiments are unable to pinpoint the symmetry. A simple estimate of pair breaking effects from an unavoidable `Na+ vacancy disorder' in an ordered Na+ lattice, at an optimal x opt ≈ 0.30 is shown to destroy a Fermi liquid based p or d-wave superconductivity. However, a robustness of superconducting and normal states, seen in experiments is pointed out and argued to imply presence of a `quantum protectorate', possibly a `spin-charge decoupling' that protects a d1+id2 and not a p-state. A calculation of Knight shift and 1 T1 in the framework of RVB mean field theory and a fit to the data of Kobayashi et al. [9] is made.
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