2015
DOI: 10.1088/1367-2630/17/5/053011
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Signatures of attosecond electronic–nuclear dynamics in the one-photon ionization of molecular hydrogen: analytical model versusab initiocalculations

Abstract: We present an analytical model based on the time-dependent WKB approximation to reproduce the photoionization spectra of an H 2 molecule in the autoionization region. We explore the nondissociative channel, which is the major contribution after one-photon absorption, and we focus on the features arising in the energy differential spectra due to the interference between the direct and the autoionization pathways. These features depend on both the timescale of the electronic decay of the autoionizing state and t… Show more

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Cited by 9 publications
(15 citation statements)
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“…As a consequence, the populated doubly excited states can efficiently ionize over a wide range of internuclear distances, from the Franck-Condon region up to well outside this region, thus leading to a broad distribution of H 2 + (1sσ g ) vibrational states. In general, the slower the autoionization, the higher the vibrational state in which H 2 + is left, because the rapidly evolving nuclear wave packet in momentum space can more efficiently overlap with higher vibrational states of H 2 + (1sσ g ) ( 35 ). Therefore, by vibrationally resolving the final state of the remaining H 2 + ion, one gains access to the dynamics of the autoionization decay: The nuclear motion acts as an internal clock that can be used to extract dynamical information about this decay.…”
Section: Resultsmentioning
confidence: 99%
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“…As a consequence, the populated doubly excited states can efficiently ionize over a wide range of internuclear distances, from the Franck-Condon region up to well outside this region, thus leading to a broad distribution of H 2 + (1sσ g ) vibrational states. In general, the slower the autoionization, the higher the vibrational state in which H 2 + is left, because the rapidly evolving nuclear wave packet in momentum space can more efficiently overlap with higher vibrational states of H 2 + (1sσ g ) ( 35 ). Therefore, by vibrationally resolving the final state of the remaining H 2 + ion, one gains access to the dynamics of the autoionization decay: The nuclear motion acts as an internal clock that can be used to extract dynamical information about this decay.…”
Section: Resultsmentioning
confidence: 99%
“…Full lines: Ab initio calculation. Dashed lines: Fit to the experimental data by using the extended Fano model described in the text [see also ( 35 )].…”
Section: Resultsmentioning
confidence: 99%
See 2 more Smart Citations
“…In general, the slower the autoionization, the higher the vibrational state in which H2+ is left, because the rapidly evolving nuclear wave packet accumulates higher momentum, thus ionizing into higher vibrational states of H2+(1s σ g ). Therefore, the nuclear motion acts as an internal clock of autoionization and the line shapes of the peaks observed in vibrationally resolved photoelectron spectra provide snapshots of the autoionization dynamics through a direct time‐energy mapping …”
Section: Molecular Photoionizationmentioning
confidence: 99%