Coherent Phonons and Quasiparticle Renormalization in Semimetals from First Principles

TL;DR

This paper develops an ab initio theoretical framework to understand and predict light-induced coherent phonons and their effects on electronic structure in semimetals, validated by experiments on antimony.

Contribution

It introduces a first-principles method to simulate displacive excitation of coherent phonons and their impact on band structure in semimetals, combining theory with experimental validation.

Findings

Validated theoretical framework with experimental data

Observed quasiparticle renormalization linked to coherent phonons

Demonstrated control of electronic properties via light-induced phonons

Abstract

Coherent phonons, light-induced coherent lattice vibrations in solids, provide a powerful route to engineer structural and electronic degrees of freedom using light. In this manuscript, we formulate an ab initio theory of the displacive excitation of coherent phonons (DECP), the primary mechanism for light-induced structural control in semimetals. Our study - based on the ab initio simulations of the ultrafast electron and coherent-phonon dynamics in presence of electron-phonon interactions - establishes a predictive computational framework for describing the emergence of light-induced structural changes and the ensuing transient band-structure renormalization arising from the DECP mechanism. We validate this framework via a combined theoretical and experimental investigation of coherent phonons in the elemental semimetal antimony. Via a Fourier analysis of time- and angle-resolved photoemission spectroscopy (tr-ARPES) measurements, we retrieve information about transient spectral features and quasiparticle renormalization arising from the coherent A1g phonon as a function of momentum, energy, time, and fluence. The qualitative and quantitative agreement between experiment and theory corroborates the first-principles approach formulated in this study. Besides advancing the fundamental understanding of electron-phonon interactions mediated by coherent phonons, this study opens new opportunities for predictively engineering structural and electronic degrees of freedom in semimetals via the DECP mechanism.