Measurement of ionization delays in atomic REMPI using photoelectron vortices

TL;DR

This paper introduces a novel method using photoelectron vortices to measure ionization time-delays in atomic REMPI with femtosecond precision, revealing delays on the order of 1 femtosecond.

Contribution

The study demonstrates the use of photoelectron vortex phase analysis for precise, interferometric measurement of ionization delays in atomic multiphoton ionization.

Findings

Measured ionization delay of approximately 1 fs in potassium atoms.

Revealed that ionization delays are much shorter than pulse durations.

Showed the effectiveness of vortex tomography for photoelectron phase analysis.

Abstract

We study time-delays in atomic multiphoton ionization (MPI) using the phase-sensitive detection of photoelectron vortices. Photoelectron vortices are created by MPI with counter-rotating circularly polarized (CRCP) ultrashort double pulse sequences. The vortices are characterized by a spiral-shaped photoelectron momentum distribution (PMD) resulting from the Ramsey-type interference of the partial photoelectron wave packets created by each pulse. The slope of the spiral arms encodes the time-delay between the partial wave packets with interferometric precision. We study the ionization time-delay in the (1+2) resonance-enhanced multiphoton ionization (REMPI) of potassium atoms using femtosecond CRCP white-light supercontinuum pulses. Pairwise interference of the partial wave packets with a reference wave packet gives rise to vortices of different rotational symmetry, which are superimposed to form the total PMD. The PMD is reconstructed tomographically and decomposed into the vortices using 3D Fourier analysis. From the energy-dependent spectral phases of the vortices, we retrieve a resonant ionization delay in the order of 1 fs, much shorter than the pulse duration. Our results demonstrate the power of photoelectron vortices for the accurate determination of photoionization time-delays and open up new perspectives for photoelectron chronoscopy including the measurement of ionization delays on the attosecond timescale.