A non-linear minimization calculation of the renormalized frequency ω in dirty d-wave superconductors

Abstract

This work performs a comparative numerical study of the impurity average self-frequency ω in an unconventional superconducting alloy with non-magnetic impurities. Two methods are used: the Levenberg-Marquardt algorithm as a non-linear minimization problem, and a fixed-point iteration procedure. The unconventional superconducting renormalized by impurities is a self-consistent complex non-linear equation with two varying parameters: the impurity concentration + and the strength of the impurities c, for which its numerical solution is a computational challenge. Throughout this study ω is the renormalized frequency, represents the inverse of the residual average lifetime τ at zero frequency, and N/N0 is the normalized superconducting density of states (DOS). This study uses an order parameter that corresponds to the high-temperature superconducting ceramics (HTS) with a well-established gap symmetry. The results reveal the computational efficiency of the non-linear minimization technique by improving the calculations of the ω computation when using a 2D parameter space (+, c), particularly in the unitary regime, where the imaginary part of ω is a complicated expression of those parameters; this allows to enhance the study of the universal behavior of this particular quantum mechanical state.