Hypothesis of two-dimensional stripe arrangement and its implications for the superconductivity in high-Tc cuprates

TL;DR

This paper proposes a 2D stripe-based microscopic model for high-Tc cuprate superconductivity, linking hole organization, pseudogap phenomena, and tunneling spectra, with predictions aligning well with experimental data.

Contribution

It introduces a novel 2D stripe arrangement hypothesis and a corresponding microscopic model that explains key superconducting properties and experimental observations in high-Tc cuprates.

Findings

Model predicts asymmetric tunneling peaks when gap-to-Tc ratio exceeds 4

Two distinct superconducting states may exist at same doping and Tc

Good quantitative agreement with experimental critical temperature and tunneling data

Abstract

The hypothesis that holes doped into high-Tc cuprate superconductors organize themselves in two-dimensional (2D) array of diagonal stripes is discussed, and, on the basis of this hypothesis, a new microscopic model of superconductivity is proposed and solved. The model describes two kinds of hole states localized either inside the stripes or in the antiferromagnetic domains between the stripes. The characteristic energy difference between these two kinds of states is identified with the pseudogap. The superconducting (SC) order parameter predicted by the model has two components, whose phases exhibit a complex dependence on the the center-of-mass coordinate. The model predictions for the tunneling characteristics and for the dependence of the critical temperature on the superfluid density show good quantitative agreement with a number of experiments. The model, in particular, predicts that the SC peaks in the tunneling spectra are asymmetric, only when the ratio of the SC gap to the critical temperature is greater than 4. It is also proposed that, at least in some high-Tc cuprates, there exist two different superconducting states corresponding to the same doping concentration and the same critical temperature. Finally, the checkerboard pattern in the local density of states observed by scanning tunneling microscopy in Bi-2212 is interpreted as coming from the states localized around the centers of stripe elements forming the 2D superstructure.