Laser-induced dissociative ionization of H$_{2}$ from the near-infrared to the mid-infrared regime

TL;DR

This study uses the Monte Carlo Wave Packet method to analyze how laser wavelength and pulse duration influence the dissociative ionization of H₂, revealing mechanisms behind kinetic energy release spectra and enabling time-resolved nuclear dynamics tracking.

Contribution

It introduces a detailed analysis of dissociative ionization in H₂ across a broad laser wavelength range using MCWP, uncovering physical origins of KER peaks and demonstrating a time-resolved pump-probe approach.

Findings

KER spectra peaks linked to specific ionization mechanisms

Large internuclear distances lead to low-energy KER peaks

Time-resolved scheme reveals dissociative energies at resonances

Abstract

We apply the Monte Carlo Wave Packet (MCWP) approach to investigate the kinetic energy release (KER) spectra of the protons following double ionization in H$_{2}$ when interacting with laser pulses with central wavelengths ranging from the near-IR (800 nm) to the mid-IR (6400 nm) regions and with durations of 3-21 laser cycles. We uncover the physical origins of the peaks in the nuclear KER spectra and ascribe them to mechanisms such as ionization following a resonant dipole transition, charge-resonance-enhanced ionization (CREI) and ionization in the dissociative limit of large internuclear distances. For relatively large pulse durations, i.e., for 15 or more laser cycles at 3200 nm and 10 or more at 6400 nm, it is possible for the nuclear wave packet in H$_{2}^{+}$ to reach very large separations. Ionization of this part of the wave packet results in peaks in the KER spectra with very low energies. These peaks give direct information about the dissociative energy in the $2p\sigma_{u}$ potential energy curve of H$_{2}^{+}$ at the one- and three-photon resonances between the $2p\sigma_{u}$ and $1s\sigma_{g}$ curves in H$_{2}^{+}$. With the MCWP approach, we perform a trajectory analysis of the contributions to the KER peaks and identify the dominant ionization pathways. Finally, we consider a pump-probe scheme by applying two delayed pulses to track the nuclear dynamics in a time-resolved setting. Low-energy peaks appear for large delays and these are used to obtain the $2p\sigma_{u}$ dissociative energy values at the one-photon resonance between the $2p\sigma_{u}$ and $1s\sigma_{g}$ curves in H$_{2}^{+}$ for different wavelengths.