Superconductivity in the kagome Hubbard model under the flat-band-preserving disorder

TL;DR

This study explores how flat-band-preserving disorder affects superconductivity in the kagome Hubbard model, revealing increased robustness of superfluid weight and a connection to flat-band states, compared to non-preserving disorder.

Contribution

It demonstrates that flat-band-preserving disorder enhances the robustness of superconductivity and maintains flat-band signatures, unlike random hopping disorder that breaks degeneracy.

Findings

Superfluid weight is more robust under flat-band-preserving disorder.

Superfluid weight shows linear interaction dependence in weak coupling.

Flat-band states are linked to enhanced superconductivity robustness.

Abstract

We investigate the disordered flat-band superconductivity within the attractive Hubbard model on the kagome lattice by contrasting the flat-band-preserving disorder [Phys. Rev. B 98, 235109 (2018)] with the random hopping disorder that breaks the flat-band degeneracy. Through Bogoliubov-de Gennes mean-field calculations, we find that the superfluid weight is much more robust under the flat-band-preserving disorder, while the system eventually undergoes a transition to an insulator as disorder becomes strong enough. The almost linear interaction-dependence of the superfluid weight in the weak coupling limit found with the flat-band-preserving disorder confirms the persistent flat-band signature, whereas the exponential behavior of a dispersive-band character arises with the random hopping counterpart. In addition, in the exact diagonalization of the one-particle density matrix, we identify an occupation spectrum structure attributed to the flat-band states, demonstrating the connection between the resilient flat band and the enhanced robustness of superconductivity.