Self-Consistent Theory of Normal-to-Superconducting Transition
Abstract
I study the normal-to-superconducting (NS) transition within the Ginzburg-Landau (GL) model, taking into account the fluctuations in the m-component complex order parameter and the vector potential A in the arbitrary dimension d, for any m. I find that the transition is of second-order and that the previous conclusion of the fluctuation-driven first-order transition is an artifact of the breakdown of the -expansion and the inaccuracy of the 1/m-expansion for physical values =1, m=1. I compute the anomalous η(d,m) exponent at the NS transition, and find η (3,1)≈-0.38. In the m∞ limit, η(d,m) becomes exact and agrees with the 1/m-expansion. Near d=4 the theory is also in good agreement with the perturbative -expansion results for m>183 and provides a sensible interpolation formula for arbitrary d and m.
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