CONDENSED MATTER

General scaling behavior of superconductors

V. R. Shaginyan^ab, A. Z. Msezane^a, S. A. Artamonov<sup>b

a</sup> Department of Physics, Clark Atlanta University, Atlanta, GA 30314, USA
^b Petersburg Nuclear Physics Institute named by B.P.Konstantinov of National Research Centre Kurchatov Institute, 188300 Gatchina, Russia

Abstract: The physics of high-$T_c$ superconductors, which has been a major topic in condensed matter physics for more than thirty years, reveals some features of conventional superconductors. We analyze the scaling of the condensation energy $E_{\Delta}$ divided by $\gamma$, $E_{\Delta}/\gamma\simeq N(0)\Delta_1^2/\gamma$, that equally applicable to both conventional and unconventional high-$T_c$ superconductors. Here $N(0)$ is the density of states, $\Delta_1$ is the maximum value of the superconducting gap and $\gamma$ is the Sommerfeld coefficient. Basing on this observation, we analyze experimental facts that reveal the general scaling properties of both high-$T_c$ and ordinary superconductors, and theoretically explain that the Homes' law $\rho_{s0}\propto T_c\sigma(T_c)$ is applicable to the both types of superconductors. Here $\sigma$ is the conductivity, $T$ is temperature and $T_c$ is the temperature of superconduction phase transition, $\lambda_D$ is the zero-$T$ penetration depth, and $\rho_{s0}$ is the superconducting electron density. For the first time, we also explain the reason of violation of the Homes' law. Our theoretical results agree well with experimental facts.

Received: 08.06.2025
Revised: 08.06.2025
Accepted: 29.06.2025

Language: English

DOI: 10.31857/S0370274X25080052