Non-Fermi-liquid behavior and d-wave superconductivity near the charge-density-wave quantum critical point

TL;DR

This paper proposes that a charge-density-wave quantum critical point explains the non-Fermi liquid behavior and d-wave superconductivity observed in high-temperature cuprates, linking charge order fluctuations to superconducting properties.

Contribution

It introduces a charge-driven quantum critical point as the key mechanism behind the normal and superconducting states in cuprates, explaining various experimental phenomena.

Findings

Non-Fermi liquid behavior at optimal doping

D-wave pairing with doping-dependent Tc

Pseudogap features consistent with experiments

Abstract

A scenario is presented, in which the presence of a quantum critical point due to formation of incommensurate charge density waves accounts for the basic features of the high temperature superconducting cuprates, both in the normal and in the superconducting states. Specifically, the singular interaction arising close to this charge-driven quantum critical point gives rise to the non-Fermi liquid behavior universally found at optimal doping. This interaction is also responsible for d-wave Cooper pair formation with a superconducting critical temperature strongly dependent on doping in the overdoped region and with a plateau in the optimally doped region. In the underdoped region a temperature dependent pairing potential favors local pair formation without superconducting coherence, with a peculiar temperature dependence of the pseudogap and a non-trivial relation between the pairing temperature and the gap itself. This last property is in good qualitative agreement with so far unexplained features of the experiments.