Atoms

20 pages, 2731 KB

Open AccessArticle

Non-Perturbative Probing Atomic Ionization by Attosecond Pulse Trains

by Sebastián D. López, Matías L. Ocello, Martín Barlari and Diego G. Arbó

Atoms 2026, 14(7), 47; https://doi.org/10.3390/atoms14070047 - 25 Jun 2026

We present a theoretical study focused on the photoelectron spectrum of near-infrared (NIR) laser-driven ionization of hydrogen atoms by attosecond pulse trains composed of several HHs of the former. We analyze the effects of increasing the intensity of the NIR probe laser to [...] Read more.

We present a theoretical study focused on the photoelectron spectrum of near-infrared (NIR) laser-driven ionization of hydrogen atoms by attosecond pulse trains composed of several HHs of the former. We analyze the effects of increasing the intensity of the NIR probe laser to account for the interference of multiple quantum pathways arising from mainbands formed in ionization by the attosecond pulse train within the strong-field approximation (SFA) beyond the commonly used first-order perturbative (in the NIR laser intensity) reconstruction of attosecond beating by interference of two-photon transitions (RABBIT). The structure of the energy bands formed in the photoelectron spectrum is governed by quantum interferences of the photoelectron wave packet released within one optical cycle of the NIR probe laser field—intracycle interference—and by the number of active high harmonic components, leading to higher-order Fourier contributions as a function of the NIR–XUV relative phase delay. We show that Fourier terms can be interpreted in terms of well-defined semiclassical trajectories. Our results demonstrate a significant departure from the standard two-path quantum-interference RABBIT picture, showing that both the phase-dependent oscillations of mainbands and sidebands and the extracted phase delays depend strongly on the probing laser intensity. The predictions of the SFA reveal that the above-threshold ionization bands exhibit systematic splitting and oscillation patterns as a function of the NIR intensity. SFA predictions are compared with results obtained within ab initio solutions of the time-dependent Schrödinger equation (TDSE), showing an excellent agreement, which evidences the minor effect of the Coulomb potential of the remaining ion on the escaping photoelectron for high energy above-threshold ionization. The precise study of the SFA reference phases is essential for the determination of the effect of the Coulomb potential on the escaping photoelectron for what these findings provide new insights into attosecond chronoscopy in the strong-field regime. Full article

(This article belongs to the Section Atomic, Molecular and Nuclear Spectroscopy and Collisions)

17 pages, 594 KB

Open AccessArticle

Modeling Atomic Structure & Behavior Through Electron Configurations

by Stephan Fritzsche, Nishita M. Hosea, Houke Huang, Tianluo Luo and Aloka K. Sahoo

Atoms 2026, 14(7), 46; https://doi.org/10.3390/atoms14070046 - 23 Jun 2026

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