Weak coupling model for s*- and d-wave superconductivity
Abstract
The phase diagram of the unconstrained t-J model is calculated using the random phase approximation. It is found that the extended s and the dx2-y2-channels are not degenerate near half filling. Extended s-pairing with a low Tc occurs only for a band containing less then 0.4 electrons or holes per unit cell, whereas in a large region around half-filling d-wave pairing is the only stable superconducting solution. At half filling superconductivity is suppressed due to the formation of the anti-ferromagnetic Mott-Hubbard insulating state. By extending the analysis to the unconstrained t-t'-J model, it is proven that, if a Fermi surface is assumed similar to the one that is known to exist in cuprous oxide superconductors, the highest superconducting Tc is reached for about 0.7 electron per site, whereas the anti-ferromagnetic solution still occurs for 1 electron per site. It is shown, that the maximum d-wave superconducting mean field transition temperature is half the maximum value that the Ne\`el temperature can have in the Mott-insulating state.
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