Localised vibrations in superconducting YBCO revealed by ultra-fast optical coherent spectroscopy

TL;DR

This study combines experimental and theoretical methods to reveal how out-of-plane phonon modes in YBCO are linked to in-plane electronic correlations, shedding light on the role of lattice vibrations in high-temperature superconductivity.

Contribution

It establishes a direct connection between c-axis phonon modes and in-plane electronic excitations in YBCO using combined spectroscopy and advanced theoretical modeling.

Findings

Identified the link between copper ion displacements and electronic correlations.

Measured the non-equilibrium Raman tensor in pump-probe experiments.

Estimated the phonon mode correlation length to be a few unit cells.

Abstract

The interaction between phonons and high-energy excitations of electronic origin in cuprates and their role in the superconducting mechanisms is still controversial. Here we use coherent vibrational time-domain spectroscopy together with density functional and dynamical mean-field theory calculations to establish a direct link between the c-axis phonon modes and the in-plane electronic charge excitations in optimally doped YBCO. The non-equilibrium Raman tensor is measured by means of the broadband 'coherent-phonon' response in pump-probe experiments and is qualitatively described by our model using DFT in frozen phonon approximation plus single band DMFT to account for the electronic correlations. The major outcome of our experimental and theoretical study is to establish the link between out-of-plane copper ions displacements and the in-plane electronic correlations, and to estimate at few unit cells the correlation length of the associated phonon mode. The approach introduced here could help revealing the complex interplay between fluctuations of different nature and spatial correlation in several strongly-correlated materials.