Attosecond photoionization dynamics with stimulated core-valence transitions

TL;DR

This paper explores how stimulated core-valence transitions influence attosecond photoionization in neon, revealing interference effects and response times comparable to current laser-based pulse characterization methods.

Contribution

It demonstrates the impact of stimulated core-valence transitions on photoelectron spectra and introduces atomic response times for different core excitations using many-body perturbation theory.

Findings

Spectral shearing depends on the pump pulse structure.

Inner-core transition response time matches state-of-the-art techniques.

Distinct behaviors observed for outer- and inner-core stimulations.

Abstract

We investigate ionization of neon atoms by an isolated attosecond pump pulse in the presence of two coherent extreme ultraviolet or x-ray probe fields. The probe fields are tuned to a core-valence transition in the residual ion and induce spectral shearing of the photoelectron distributions. We show that the photoelectron-ion coincidence signal contains an interference pattern that depends on the temporal structure of the attosecond pump pulse and the stimulated core-valence transition. Many-body perturbation theory is used to compute "atomic response times" for the processes and we find strikingly different behavior for stimulation to the outer-core hole (2p - 2s) and stimulation to the inner-core hole (2p - 1s). The response time of the inner-core transition is found to be comparable to that of state-of-the-art laser-based characterization techniques for attosecond pulses.