Phonons, electronic charge response and electron-phonon interaction in the high-temperature superconductors

TL;DR

This paper uses linear response theory to analyze phonon behavior, charge response, and electron-phonon interactions in high-temperature superconductors, revealing the significance of nonlocal coupling and non-adiabatic effects in their properties.

Contribution

It provides a comprehensive theoretical framework for understanding phonon dispersion, charge response, and electron-phonon interactions in HTSCs, including the role of nonlocal coupling and non-adiabatic effects.

Findings

Strong renormalization of in-plane oxygen bond-stretching modes upon doping

Nonlocal coupling of ions to localized charge fluctuations drives mode softening

Phonon-plasmon mixing and non-adiabatic effects are important for pairing mechanisms

Abstract

We investigate in the framework of linear response theory the complete phonon dispersion, phonon induced electronic charge response, electron-phonon interaction and dielectric and infrared properties of the high-temperature superconductors (HTSC's). In particular the experimentally observed strong renormalization of the in-plane oxygen bond-stretching modes (OBSM) which appear upon doping in the HTSC's is discussed. It is shown that the characteristic softening, indicating a strong EPI, is most likely a generic effect of the CuO plane and is driven by a nonlocal coupling of the displaced ions to the localized charge-fluctuations (CF's) at the Cu and O ions. The different behaviour of the OBSM during the insulator-metal transition via the underdoped phase is calculated and from a comparison of these modes conclusions about the electronic state in the HTSC's are drawn. The underdoped state is modelled in terms of a charge response which is insulator-like at the Cu and is competing with a metallic charge response at the O-network in the CuO plane. For the non-cuprate HTSC Ba-Bi-O also a strong renormalization of the OBSM is predicted. C-axis polarized infrared and Raman-active modes of the HTSC's are calculated in terms of CF's and anisotropic dipole-fluctuations and the problem of a metallic character of the BiO planes is studied.Interlayer phonons and their accompanying charge response are investigated. Depending on the interlayer coupling calculations are performed from the static, adiabatic- to the non-adiabatic regime.It is shown that phonon-plasmon mixing and a strong long-ranged non-adiabatic EPI becomes evident within a certain region around the c-axis. Both the OBSM and the non-adiabatic coupled c-axis phonon-plasmon modes are found to be important for pairing in the HTSC's.