Diamagnetic response and phase stiffness for interacting isolated narrow bands

TL;DR

This paper develops a non-perturbative theoretical framework to compute the maximum superconducting phase stiffness and transition temperature in narrow band systems, emphasizing the roles of remote band integration and density interactions.

Contribution

It introduces a general method to calculate electromagnetic response and phase stiffness in narrow bands without mean-field approximations, applicable to topological and non-topological models.

Findings

Framework accurately predicts upper bounds on $T_c$.

Explicit calculations show the importance of remote bands and interactions.

Comparison with numerical results validates the approach.

Abstract

A platform that serves as an ideal playground for realizing ``high'' temperature superconductors are materials where the electrons' kinetic energy is completely quenched, and interactions provide the only energy scale in the problem for $T_c$. However, when the non-interacting bandwidth for a set of isolated bands is small compared to the scale of the interactions, the problem is inherently non-perturbative and requires going beyond the traditional mean-field theory of superconductivity. In two spatial dimensions, $T_c$ is controlled by the superconducting phase stiffness. Here we present a general theoretical framework for computing the electromagnetic response for generic model Hamiltonians, which controls the maximum possible superconducting phase stiffness and thereby $T_c$, without resorting to any mean-field approximation. Importantly, our explicit computations demonstrate that the contribution to the phase stiffness arises from (i) ``integrating out'' the remote bands that couple to the microscopic current operator, and (ii) the density-density interactions projected onto the isolated narrow bands. Our framework can be used to obtain an upper bound on the phase stiffness, and relatedly the superconducting transition temperature, for a range of physically inspired models involving both topological and non-topological narrow bands with arbitrary density-density interactions. We discuss a number of salient aspects of this formalism by applying it to a specific model of interacting flat bands and compare it against the known $T_c$ from independent numerically exact computations.