Mapping and controlling ultrafast dynamics of highly excited 
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 molecules by VUV-IR pump-probe schemes

Sturm, Felix; Tong, Xiao-Min; Palacios, Alicia; Wright, Travis; Zalyubovskaya, I.; Ray, D.; Shivaram, Niranjan; Martín, Fernando; Belkacem, A.; Ranitovic, Predrag; Weber, Th.

doi:10.1103/physreva.95.012501

Cited by 11 publications

(16 citation statements)

References 31 publications

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“…Thus, the second challenge is to find the appropriate detection mechanism to trace dynamics and to even image them. While techniques like laser-induced fluorescence [101] represent a great tool to trigger and detect molecular systems with transitions in the UV to the near infrared (NIR) range, one would need a pump wavelength of ∼100 nm [102] to reach the first excited state of the neutral H 2 molecule-a challenge even today as we will see later [103][104][105][106], but not accessible 20 years ago. The desire to resolve vibrational and electronic dynamics in H 2 has thus triggered two branches of development-shorter laser pulses, and advanced and creative imaging techniques, which will be introduced in the following.…”

Section: Imaging Nuclear Dynamics-techniques and Resultsmentioning

confidence: 99%

H₂: the benchmark molecule for ultrafast science and technologies

Ibrahim

Lefebvre

Bandrauk

et al. 2018

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

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This review article focuses on imaging and controlling ultrafast dynamics of the hydrogen molecule and its cation, initiated by ultrashort laser pulses. We discuss the mechanisms underlying these dynamics and theoretical methods to describe them. A broad variety of defining and influencing theoretical and experimental results is presented. We put special emphasis on the required experimental techniques, many of which have been developed in view of imaging the fastest of all nuclear dynamics.

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Section: Imaging Nuclear Dynamics-techniques and Resultsmentioning

confidence: 99%

H₂: the benchmark molecule for ultrafast science and technologies

Ibrahim

Lefebvre

Bandrauk

et al. 2018

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

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“…The net-2ω channel yields higher kinetic energy than the 1ω dissociation. Here, we discuss only on the net-2ω channel as this channel is easy to distinguish regarding inter-channel mixing compared to the 1ω channel [21]. Fig.…”

mentioning

confidence: 99%

Orientation-dependent dissociative ionization of H2 in strong elliptic laser fields: Modification of the release time through molecular orientation

et al. 2020

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We investigate the photoelectron angular emission distributions obtained by strong field dissociative ionization of H2 using cold target recoil ion momentum spectroscopy. In case of employing laser light with an ellipticity close to 0.9 and an intensity of 1.0 × 10 14 W/cm 2 , we find that the most probable release-time of the electron does not generally coincide with the time when the laser field maximizes. The release-time is affected by the molecular orientation. In addition, we observe that the width of the release-time distribution depends on molecular orientation. We attribute this observation to a two-center-interference confirming a prediction by Serov et al. [1].

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“…Theory based on the spectral method has also given support to time‐resolved experiments that make use of an APT in combination with one or several weak IR fields, showing that the ratio between dissociative and nondissociative ionization can be manipulated in H 2 and D 2 by just varying the photon energy of the pulses.…”

Section: Molecular Attosecond Dynamicsmentioning

confidence: 99%

The quantum chemistry of attosecond molecular science

Palacios

Martı́n

2019

WIREs Comput Mol Sci

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With the advent of attosecond light pulses at the beginning of this century, the possibility to perform real-time observations of electron motion in molecules has spurred impressive theoretical developments aimed at providing support and guidance to numerous, but still incipient, experimental efforts devoted to understand chemistry at its ultimate temporal frontier: the attosecond. The first real-time observation of electron dynamics in a relatively large molecule, phenylalanine, was reported in 2014. This would have been difficult without the help of theory, since observations in this emerging field, recently coined attochemistry, are still indirect.While standard Quantum Chemistry methods can describe excited bound-state dynamics, new approaches incorporating scattering theory formalisms are needed to understand the interaction with attosecond pulses. Indeed, due to their short wavelengths, lying in the XUV and X-ray spectral regions, the interaction of such pulses with any molecule inevitably leads to ionization, which requires describing the molecular ionization continuum. Also, because of their short duration (i.e., large bandwidth), ionization is accompanied by the formation of a molecular electronic wave packet (i.e., a coherent superposition of electronic states), which evolves in time and dictates the fate of the molecule at the longer time scales where chemistry shows up. Although much has already been done up to date, current bottlenecks in the field are to account for electron correlations during the ionization process and for the coupled electron and nuclear dynamics that follows. Past and ongoing theoretical efforts are described here along with experimental work towards the solid establishment of attochemistry. This article is categorized under: Electronic Structure Theory > Ab Initio Electronic Structure Methods Software > Quantum Chemistry Theoretical and Physical Chemistry > Spectroscopy K E Y W O R D S attochemistry, attosecond dynamics, molecular dynamics, molecular ionization, ultrafast

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Mapping and controlling ultrafast dynamics of highly excited H2 molecules by VUV-IR pump-probe schemes

Cited by 11 publications

References 31 publications

H₂: the benchmark molecule for ultrafast science and technologies

H₂: the benchmark molecule for ultrafast science and technologies

Orientation-dependent dissociative ionization of H2 in strong elliptic laser fields: Modification of the release time through molecular orientation

The quantum chemistry of attosecond molecular science

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Mapping and controlling ultrafast dynamics of highly excited H2 molecules by VUV-IR pump-probe schemes

Cited by 11 publications

References 31 publications

H2: the benchmark molecule for ultrafast science and technologies

H2: the benchmark molecule for ultrafast science and technologies

Orientation-dependent dissociative ionization of H2 in strong elliptic laser fields: Modification of the release time through molecular orientation

The quantum chemistry of attosecond molecular science

Contact Info

Product

Resources

About

H₂: the benchmark molecule for ultrafast science and technologies

H₂: the benchmark molecule for ultrafast science and technologies