Fluctuating charge order in the cuprates: spatial anisotropy and feedback from superconductivity

TL;DR

This paper investigates the anisotropic static charge susceptibility in underdoped cuprates, revealing how charge order correlation lengths decrease with superconductivity and identifying two distinct charge order transitions.

Contribution

It provides a detailed analysis of the anisotropic charge susceptibility and its evolution with superconductivity, supported by experimental data, and distinguishes the effects on charge-density and current components.

Findings

Correlation lengths are larger in the longitudinal direction.

Superconductivity reduces charge order correlation lengths.

Two distinct charge order transitions occur at zero temperature.

Abstract

We analyze the form of static charge susceptibility $\chi(q)$ in underdoped cuprates near axial momenta $(Q,0)$ and $(0,Q)$ at which short-range static charge order has been observed. We show that the momentum dependence of $\chi (q)$ is anisotropic, and the correlation length in the longitudinal direction is larger than in the transverse direction. We show that correlation lengths in both directions decrease once the system evolves into a superconductor, as a result of the competition between superconductivity and charge order. These results are in agreement with resonant x-ray scattering data [R. Comin et al., Science 347, 1335 (2015)]. We also argue that density and current components of the charge order parameter are affected differently by superconductivity --- the charge-density component is reduced less than the current component and hence extends deeper into the superconducting state. This gives rise to two distinct charge order transitions at zero temperature.