THERMODYNAMICS OF GAUSSIAN FLUCTUATIONS AND PARACONDUCTIVITY IN LAYERED SUPERCONDUCTORS

Abstract

A detailed theoretical analysis of the Gaussian fluctuations of the order parameter in layered superconductors is performed within the Ginzburg–Landau (GL) theory. The available results for the Gaussian fluctuations are systematized and a number of novel formulae for the fluctuation magnetization, nonlinear magnetic susceptibility, heat capacity and high-frequency conductivity in layered superconductors are derived. We propose several new prescriptions: how to determine the life-time constant of fluctuation Cooper pairs τ0, the in-plane coherence length ξab(0), the energy cutoff parameter [Formula: see text] and the Ginzburg number ∊ Gi . It is demonstrated, for example, how the spectroscopy of the life-time can be used to verify the existence of depairing mechanisms in layered cuprates. The ultraviolet regularization of the GL free energy is carried out by means of the well-known from the field theory ζ-function method. We further show that the archetype of the latter method has its origin in the century of enlightenment and the novel result is that the fluctuation part of the thermodynamic variables of the layered superconductors can be expressed in terms of the Euler Γ-function and its derivatives. Universal scaling curves for the magnetic field dependence of the paraconductivity σab(T c ,B), fluctuation magnetization M(T c ,B) and the heat capacity C(T c ,B) are found for the quasi-2D superconductors at T c and further related to the form-factor of the Cooper pairs.