Tracing transient charges in expanding clusters

Schütte, Bernd; Vrakking, Marc J. J.; Rouzée, Arnaud

doi:10.1103/physreva.95.063417

Cited by 4 publications

(3 citation statements)

References 38 publications

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“…The shoulder was previously attributed to correlated electronic decay processes [36] and cascades of intra-Rydberg interatomic Coulombic decay transitions [37,38] producing singly charged ions and electrons with kinetic energies up to the ionization potential of the cluster atoms, i.e., up to about 15.8 eV for Ar. Further examples of recently discovered correlation-driven cluster ionization processes include collective autoionization [39], autoionization of spin-orbit-excited states [40], as well as the relaxation of multiply charged ions by Auger decay [41] and autoionization [42].…”

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confidence: 99%

“…Atomic ionization events due to tunneling and electron impact are modeled via Monte Carlo sampling using effective quantum-mechanical rates, including local-field induced ionization potential depression [26]. Note that atomic autoionization [40,41] and many-body recombination processes in the nanoplasma, which dominantly couple to highly excited states [44], are only qualitatively included in the correlated classical treatment. The MD results obtained for Ar 5083 using parameters similar to the experiment reproduce two of the most prominent features of the measured electron spectra and show two exponential contributions with strongly differing decay constants; see Fig.…”

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Low-Energy Electron Emission in the Strong-Field Ionization of Rare Gas Clusters

et al. 2018

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Clusters and nanoparticles have been widely investigated to determine how plasmonic near fields influence the strong-field induced energetic electron emission from finite systems. We focus on the contrary, i.e., the slow electrons, and discuss a hitherto unidentified low-energy structure (LES) in the photoemission spectra of rare gas clusters in intense near-infrared laser pulses. For Ar and Kr clusters we find, besides field-driven fast electrons, a robust and nearly isotropic emission of electrons with <4 eV kinetic energies that dominates the total yield. Molecular dynamics simulations reveal a correlated few-body decay process involving quasifree electrons and multiply excited ions in the nonequilibrium nanoplasma that results in a dominant LES feature. Our results indicate that the LES emission occurs after significant nanoplasma expansion, and that it is a generic phenomenon in intense laser nanoparticle interactions, which is likely to influence the formation of highly charged ions.

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Low-Energy Electron Emission in the Strong-Field Ionization of Rare Gas Clusters

et al. 2018

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“…Many interesting properties of nanoplasmas come from the enhancement of recombination processes due to the large number of confined electrons and positive ions [13,14]. The decay of a nanoplasma is governed by a complex interplay of Coulomb explosion and hydrodynamic forces leading to shock shells in the outer Debye layer [15][16][17][18]. Single-shot x-ray diffraction imaging of the nanoplasma evolution in rare-gas clusters revealed sub-picosecond dynamics [19], and a core-shell structure [20].…”

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Evolution and ion kinetics of a XUV-induced nanoplasma in ammonia clusters

Michiels¹,

LaForge²,

Bohlen³

et al. 2021

J. Phys. B: At. Mol. Opt. Phys.

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High-intensity extreme ultraviolet (XUV) pulses from a free-electron laser can be used to create a nanoplasma in clusters. In reference Michiels et al (2020 Phys. Chem. Chem. Phys. 22 7828–34) we investigated the formation of excited states in an XUV-induced nanoplasma in ammonia clusters. In the present article we expand our previous study with a detailed analysis of the nanoplasma evolution and ion kinetics. We use a time-delayed UV laser as probe to ionize excited states of H and H 2 + in the XUV-induced plasma. Employing covariance mapping techniques, we show that the correlated emission of protons plays an important role in the plasma dynamics. The time-dependent kinetic energy of the ions created by the probe laser is measured, revealing the charge neutralization of the cluster happens on a sub-picosecond timescale. Furthermore, we observe ro-vibrationally excited molecular hydrogen ions H 2 + * being ejected from the clusters. We rationalize our data through a qualitative model of a finite-size non-thermal plasma.

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Tracing Nonlinear Cluster Dynamics Induced by Intense XUV, NIR and MIR Laser Pulses

Schütte¹

2017

Springer Series in Chemical Physics

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Tracing transient charges in expanding clusters

Cited by 4 publications

References 38 publications

Low-Energy Electron Emission in the Strong-Field Ionization of Rare Gas Clusters

Low-Energy Electron Emission in the Strong-Field Ionization of Rare Gas Clusters

Evolution and ion kinetics of a XUV-induced nanoplasma in ammonia clusters

Tracing Nonlinear Cluster Dynamics Induced by Intense XUV, NIR and MIR Laser Pulses

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