Detailed study of quantum path interferences in high harmonic generation driven by chirped laser pulses

TL;DR

This paper explores how electron quantum path interference affects high harmonic generation driven by ultrashort chirped laser pulses, revealing how control parameters influence interference patterns and harmonic spectra.

Contribution

It provides a detailed analysis of quantum path interferences in HHG with chirped pulses, incorporating macroscopic effects and offering insights for experimental control.

Findings

Interference patterns depend on pulse duration, intensity, and frequency.

Chirp control can tune the periodicity of harmonic oscillations.

Spectral Maker fringes are influenced by quantum path interferences.

Abstract

We investigate the electron quantum path interference effects during high harmonic generation in atomic gas medium driven by ultrashort chirped laser pulses. To achieve that, we identify and vary the different experimentally relevant control parameters of such a driving laser pulse influencing the high harmonic spectra. Specifically, the impact of the pulse duration, peak intensity and instantaneous frequency is studied in a self-consistent manner based on Lewenstein formalism. Simulations involving macroscopic propagation effects are also considered. The study aims to reveal the microscopic background behind a variety of interference patterns capturing important information both about the fundamental laser field and the generation process itself. The results provide guidance towards experiments with chirp control as a tool to unravel, explain and utilize the rich and complex interplay between quantum path interferences including the tuning of the periodicity of the intensity dependent oscillation of the harmonic signal, and the curvature of spectrally resolved Maker fringes.