Abstract
High harmonic generation (HHG) is an extremely nonlinear effect generating coherent broadband radiation and pulse durations reaching attosecond timescales. Conventional models of HHG that treat the driving and emitted fields classically are usually very successful but inherently cannot capture the quantum-optical nature of the process. Although prior work considered quantum HHG, it remains unknown in what conditions the spectral and statistical properties of the radiation depart considerably from the known phenomenology of HHG. The discovery of such conditions could lead to novel sources of attosecond light having squeezing and entanglement. Here, we present a fully-quantum theory of extreme nonlinear optics, predicting quantum effects that alter both the spectrum and photon statistics of HHG, thus departing from all previous approaches. We predict the emission of shifted frequency combs and identify spectral features arising from the breakdown of the dipole approximation for the emission. Our results show that each frequency component of HHG can be bunched and squeezed and that each emitted photon is a superposition of all frequencies in the spectrum, i.e., each photon is a comb. Our general approach is applicable to a wide range of nonlinear optical processes, paving the way towards novel quantum phenomena in extreme nonlinear optics.
Highlights
High harmonic generation (HHG) is an extremely nonlinear effect generating coherent broadband radiation and pulse durations reaching attosecond timescales
The formalism constructed here is based on the idea of using quantum electrodynamical perturbation theory for bound electrons that are dressed by an external field (SFQED), similar to the approach described in[24,26]
The quantization of electromagnetic fields enables analyzing the quantum statistics of the emitted field and the driving field. wQhWjiαchkeσciioesÀnisdωiekdtse,crrwiabhneederleebcyαtrkoσanirmcepsuyrletsistmeemnotdsdertihvceoenhceboryehneatrestnsrttoantsegt:altaeψsse’larsepfiraerla1⁄4d, kσ meters that can be shown to be equal to the complex amplitudes of the Fourier components of the classical description of the incident driving field; k refers to the wavevector of a plane wave in free space, σ to its polarization, and ωk = ck = c|k| to its frequency, with c the speed of light in vacuum
Summary
High harmonic generation (HHG) is an extremely nonlinear effect generating coherent broadband radiation and pulse durations reaching attosecond timescales. More recent studies[24,25,26] developed a quantum formalism for HHG in which the electron states are dressed by the driving classical field, and the radiation is seen as spontaneous emission from these time-dependent dressed states.
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