Origin of the high-energy kink or the waterfall effect in the photoemission spectrum of the ${\rm Bi_2Sr_2CaCu_2O_8}$ high-temperature superconductor

TL;DR

This study investigates the origin of the high-energy waterfall effect in the photoemission spectra of Bi2212, demonstrating it results from strong quasiparticle coupling to electronic excitations rather than matrix element artifacts.

Contribution

The paper provides realistic computations including matrix element effects and self-energy corrections, confirming the waterfall effect as evidence of strong quasiparticle-electronic excitation coupling.

Findings

Waterfall effect persists after including matrix element effects.

Strong quasiparticle coupling to electronic excitations causes the waterfall.

Matrix elements influence spectral shape but do not produce the effect.

Abstract

The high-energy kink or the waterfall effect seen in the photoemission spectra of the cuprates is suggestive of the coupling of the quasiparticles to a high energy bosonic mode with implications for the mechanism of superconductivity. Recent experiments however indicate that this effect may be an artifact produced entirely by the matrix element effects, i.e. by the way the photoemitted electron couples to the incident photons in the emission process. In order to address this issue directly, we have carried out realistic computations of the photo-intensity in ${\rm Bi_2Sr_2CaCu_2O_8}$ (Bi2212) where the effects of the matrix element are included together with those of the corrections to the self-energy resulting from electronic excitations. Our results demonstrate that while the photoemission matrix element plays an important role in shaping the spectra, the waterfall effect is a clear signature of the presence of strong coupling of quasiparticles to electronic excitations.