High-Temperature Superconductivity from Finite-Range Attractive Interaction
Abstract
In this letter we consider -dimensional interacting Fermi liquids, and demonstrate that an attractive interaction with a finite range that is much greater than the Fermi wavelength breaks the conventional BCS theory of superconductivity. In contrast to the BCS prediction of a finite superconducting gap for all attractive contact interactions, we show that a finite-range interaction does not induce a superconducting gap. Instead, the pair susceptibility develops a power-law singularity at zero momentum and zero frequency signaling quantum critical behavior without long-range ordering. Starting from this, we show that superconductivity can be stabilized by adding a short-range attractive interaction, which is always present in real electronic systems. As an example, we consider a layered quasi-two-dimensional material with attractive electron-electron interactions mediated by optical phonons. We demonstrate a dome shape of the critical temperature versus doping, strongly suppressed isotope effect, and a weak dependence of the optimal doping and maximal on the interaction range at , is the Fermi energy. We believe that these results could be relevant to high-temperature superconductors.
Cite
@article{arxiv.2502.11624,
title = {High-Temperature Superconductivity from Finite-Range Attractive Interaction},
author = {Dmitry Miserev and Joel Hutchinson and Herbert Schoeller and Jelena Klinovaja and Daniel Loss},
journal= {arXiv preprint arXiv:2502.11624},
year = {2025}
}