Towards the discovery of high critical magnetic field superconductors

Abstract

Superconducting materials are of significant technological relevance for a broad range of applications, and intense research efforts aim at enhancing the critical temperature Tc. Intriguingly, while numerous studies have explored different computational and machine-learning routes to predict Tc, the fundamental role of the critical magnetic field has so far been overlooked. Here we open a new frontier in superconductor discovery by presenting a consistent computational database of critical fields Hc, Hc1, and Hc2 for over 7300 electron-phonon-paired superconductors covering distinct materials classes. A theoretical framework is developed that combines α2F(ω) spectral functions and highly accurate Fermi surfaces from density functional theory with clean-limit Eliashberg theory to obtain the coherence lengths, London penetration depths, and Ginzburg-Landau parameters. We discover an unexpectedly large number of Type-I superconductors and show that larger unit cells generically support higher critical fields and Type-II behavior. We identify the importance of going beyond BCS theory by including strong-coupling corrections to the superconducting gap and electron-phonon renormalizations of the effective mass for predictions of critical fields across materials. These results provide a framework for foundational AI models that realize the concept of inverse materials design for high-Tc and high-critical-field superconductors.