On the Quantum-Optical Nature of High Harmonic Generation

TL;DR

This paper develops a fully quantum electrodynamical model of high harmonic generation (HHG), revealing quantum effects like shifted frequency combs, superposition of frequencies, and breakdown of classical approximations, with implications for quantum optics.

Contribution

It introduces a comprehensive quantum theory of HHG that predicts novel quantum phenomena and spectral features beyond classical models.

Findings

Prediction of shifted frequency combs from atomic transitions

Identification of spectral features from dipole approximation breakdown

HHG photons as superpositions of all spectrum frequencies

Abstract

High harmonic generation (HHG) is an extremely nonlinear effect, where a medium is driven by a strong laser field, generating coherent broadband radiation with photon energies ranging up to the X-ray and pulse durations reaching attosecond timescales. Conventional models of HHG treat the medium quantum mechanically, while the driving and emitted fields are treated classically. Such models are usually very successful, but inherently cannot capture the quantum-optical nature of the process. Despite prior works considering quantum HHG, it is still not known in what circumstances the spectral and statistical properties of the radiation considerably depart from the known phenomenology of HHG. Finding such regimes in HHG could lead to novel sources of attosecond light with intrinsically quantum statistics such as squeezing and entanglement. In this work, we present a fully quantum electrodynamical theory of extreme nonlinear optics with which we predict new quantum effects that alter both spectral and statistical properties of HHG. We predict the emission of shifted frequency combs resulting from transitions between perturbed states of the driven atom, and identify new spectral features that arise from the breakdown of the dipole approximation for the emission. Moreover, we find that each HHG emitted photon is a superposition of all frequencies in the spectrum - e.g., HHG creates single photon combs. We also describe how the HHG process changes in the single atom regime, and discuss how our various predictions can be tested experimentally. Our approach is also applicable to a wide range of nonlinear optical processes, paving the way toward novel quantum information techniques in the EUV and X-ray, and in ultrafast quantum optics.