A non-BCS mechanism for superconductivity in underdoped cuprates via attraction between spin vortices

TL;DR

This paper introduces a novel non-BCS mechanism for superconductivity in underdoped cuprates, based on an attraction between spin vortices, leading to pairing and a finite Nernst signal prior to the superconducting transition.

Contribution

It proposes a gauge-theoretic non-BCS mechanism involving spin vortex attraction and pairing, explaining key experimental features in underdoped cuprates.

Findings

Spin vortex attraction leads to charge carrier pairing.

A gauge force induces spin pairing from charge pairs.

Finite Nernst signal appears before superconductivity.

Abstract

We propose a non-BCS mechanism for superconductivity in hole-underdoped cuprates based on a gauge approach to the {\it t-J} model. The gluing force is an attraction between spin vortices centered on the empty sites of two opposite N\'eel sublattices, leading to pairing of charge carriers. In the presence of these pairs, a gauge force coming from the single occupancy constraint induces, in turn, the pairing of the spin carriers. The combination of the charge and spin pairs gives rise to a finite density of incoherent hole pairs, leading to a finite Nernst signal as precursor to superconductivity. The true superconducting transition occurs at an even lower temperature, via a 3D XY-type transition. The main features of this non-BCS description of superconductivity are consistent with the experimental results in underdoped cuprates, especially the contour plot of the Nernst signal.