Revealing laser-coherent electron features using phase-of-the-phase spectroscopy

TL;DR

This paper extends phase-of-the-phase spectroscopy to two-color circularly polarized laser fields, enabling the extraction of laser-coherent electron features from complex photoelectron spectra through analysis of higher harmonic signals.

Contribution

It introduces a novel application of PoP spectroscopy to complex laser fields and demonstrates its ability to isolate coherent electron emission in realistic experimental conditions.

Findings

Higher harmonics of PoP signal reveal laser-coherent electron features.

Method effectively distinguishes coherent emission from incoherent background.

Simulation confirms feasibility under realistic experimental parameters.

Abstract

Phase-of-the-phase (PoP) spectroscopy is extended to two-color laser fields having a circularly counter-rotating polarization. In particular, the higher harmonics of the (two-color) phase information are analyzed in order to extract the laser-coherent part of the photoelectron spectra taken under complex target conditions. We illustrate this with a proof-of-principle simulation by considering strong-field electron emission from argon atoms within helium nanodroplets under realistic experimental conditions, i.e., a limited number of photoemission events. Multiple elastic scattering on neutral helium atoms creates a laser-incoherent background, but the higher harmonics of the PoP-signal allow to resolve the coherent contribution to the photoemission.