The magnetic nature of superconductivity in doped cuprates

TL;DR

This paper explores the magnetic properties of doped cuprate superconductors within a kinetic energy driven framework, linking quasiparticle coherence, doping levels, and magnetic excitations to experimental neutron scattering results.

Contribution

It introduces a theoretical approach that explains magnetic features and doping dependence of superconductivity in cuprates, aligning with experimental observations.

Findings

Quasiparticle coherent weight varies with doping, peaking at optimal doping.

The model reproduces key features of neutron scattering experiments.

Superconducting transition temperature correlates with quasiparticle coherence.

Abstract

Within the kinetic energy driven superconducting mechanism, the magnetic nature of cuprate superconductors is discussed. It is shown that the superconducting state is controlled by both charge carrier gap function and quasiparticle coherent weight. This quasiparticle coherent weight grows linearly with the hole doping concentration in the underdoped and optimally doped regimes, and then decreases with doping in the overdoped regime, which leads to that the maximal superconducting transition temperature occurs around the optimal doping, and then decreases in both underdoped and overdoped regimes. Within this framework, we calculate the dynamical spin structure factor of cuprate superconductors, and reproduce all main features of inelastic neutron scattering experiments, including the energy dependence of the incommensurate magnetic scattering at both low and high energies and commensurate resonance at intermediate energy.