Strong Laser Field-Driven Coupled Electron–Nuclear Dynamics: Quantum vs Classical Description

Pandey, Gaurav; Ghosh, Sandip; Tiwari, Ashwani K.

doi:10.1021/acs.jpca.3c05047

Cited by 3 publications

(9 citation statements)

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“…They show that the molecular structure is imprinted onto the elliptic-dichroism parameter for both monochromatic and bichromatic driving fields, so that it can be used as a tool to analyze the electron dynamics in molecules. Pandey et al present a theoretical study of the coupled electron–nuclear dynamics in the H 2 + molecular ion under the influence of an intense laser field, using both quantum and classical dynamical methods to analyze the validity of simpler classical methods for the description of strong-field phenomena involving both electronic and nuclear motions . Labeye et al have investigated the ultrafast vibronic dynamics triggered by intense femtosecond infrared pulses in small molecules .…”

Section: Strong Fieldsmentioning

confidence: 99%

“…Pandey et al present a theoretical study of the coupled electron−nuclear dynamics in the H 2 + molecular ion under the influence of an intense laser field, using both quantum and classical dynamical methods to analyze the validity of simpler classical methods for the description of strong-field phenomena involving both electronic and nuclear motions. 14 Labeye et al have investigated the ultrafast vibronic dynamics triggered by intense femtosecond infrared pulses in small molecules. 15 They provide a new interpretation of the observed nuclear wave packet dynamics and reveal intricate features in the fieldinduced nuclear motion that are not accounted for by existing models.…”

Section: ■ Charge Dynamicsmentioning

confidence: 99%

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Virtual Special Issue on Attosecond Chemistry

Martín,

Calegari,

Vozzi

et al. 2024

J. Phys. Chem. A

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Section: Strong Fieldsmentioning

confidence: 99%

Section: ■ Charge Dynamicsmentioning

confidence: 99%

Virtual Special Issue on Attosecond Chemistry

Martín,

Calegari,

Vozzi

et al. 2024

J. Phys. Chem. A

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“…In general, physical chemistry and chemistry can greatly benefit from these developments because new possibilities to steer and observe chemical reactions may arise in the future. 55,56 The Nobel Prize in Physics 2023 was awarded to Pierre Agostini, Ferenc Krausz, and Anne L'Huillier for experimental methods that generate attosecond pulses of light for the study of electron dynamics in matter. 57 The duration of the light pulses applied for probing and control purposes is of crucial importance regarding the applicability of the mapping or control scheme under consideration.…”

Section: Introductionmentioning

confidence: 99%

“…Attosecond science has given access to the natural time scale of electronic and fast nuclear motion. − Light pulses with subfemtosecond duration are now routinely generated in high-harmonic generation sources and X-ray-free electron lasers. In general, physical chemistry and chemistry can greatly benefit from these developments because new possibilities to steer and observe chemical reactions may arise in the future. , The Nobel Prize in Physics 2023 was awarded to Pierre Agostini, Ferenc Krausz, and Anne L’Huillier for experimental methods that generate attosecond pulses of light for the study of electron dynamics in matter…”

Section: Introductionmentioning

confidence: 99%

Attosecond Probing of Nuclear Vibrations in the D₂⁺ and HeH⁺ Molecular Ions

Biró,

Csehi

2024

J. Phys. Chem. A

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We study the ultrafast photodissociation of small diatomic molecules using attosecond laser pulses of moderate intensity in the (extreme) ultraviolet regime. The simultaneous application of subfemtosecond laser pulses with different photon energies�resonant in the region of the molecular motion�allows one to monitor the vibrational dynamics of simple diatomics, like the D 2 + and HeH + molecular ions. In our real-time wave packet simulations, the nuclear dynamics is initiated either by sudden ionization (D 2 + ) or by explicit pump pulses (HeH + ) via distortion of the potential energy of the molecule. The application of time-delayed attosecond pulses leads to the breakup of the molecules, and the information on the underlying bound-state dynamics is imprinted in the kinetic energy release (KER) spectra of the outgoing fragments. We show that the KER-delay spectrograms generated in our ultrafast pump−probe schemes are able to reconstruct the most important features of the molecular motion within a given electronic state, such as the time period or amplitude of oscillations, interference patterns, or the revival and splitting of the nuclear wave packet. The impact of probe pulse duration, which is key to the applicability of the presented mapping scheme, is investigated in detail.

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“…On the other hand, for the study of both electronic and nuclear dynamics with unprecedented spatial as well as temporal resolution imaging of electron wavepacket, ultrashort strong laser pulses are currently regularly utilized. − Ever since the production of attosecond pulses, − the horizon of attosecond science has expanded gradually due to routine generation of such pulses with the aid of higher harmonic generation sources and X-ray-free electron lasers. − Indeed, attosecond pulses are widely used to the direct observation and control of the electrons and electronic wavepackets along with probing of molecular dipoles in attosecond domain, − since the time scale of such pulses match the natural time scale of electronic motion in molecules. , It is noteworthy that Agostini, Krausz, and L’Huillier were awarded the Nobel Prize in Physics 2023 for developing the experimental methods to generate attosecond pulses for studying electron dynamics. In this regard, normalH 2 + , being the simplest, yet most important prototype system for laser-induced molecular fragmentation process, is usually the extensively studied molecular system to understand the complex process of coupled electron–nuclear dynamics, − in particular under the influence of intense laser pulses. On the other hand, for a few-cycle pulse, the carrier-envelope phase (CEP) acts as an important controlling knob for electronic motions, where for the case of normalH 2 + , the electron can preferentially stick to either one of the two protons − due to the interference of odd and even photon number pathways as inspected by a lot of experimental − ,, as well as theoretical −…”

Section: Introductionmentioning

confidence: 99%

Efficient Control of Electron Localization and Probability Modulation with Synthesized Two-Color Intense Laser Pulses

Ghosh,

Pandey,

Tiwari

2024

J. Phys. Chem. A

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A coupled electron−nuclear dynamical study at attosecond time scale is performed on the HD + and H 2 + molecular ions under the influence of synthesized intense two-color electric fields. We have employed ω − 2ω and also, ω − 3ω two-color fields in the infrared/mid-infrared regime to study the different fragmentation processes originating from the interference of n − (n + i) (i = 1, 2) photon absorption pathways. The branching ratios corresponding to different photofragments are controlled by tuning the relative phase as well as intensity of the two-color pulses, while the effect of the initial nuclear wave function is also studied by taking an individual vibrational eigenstate or a coherent superposition of several eigenstates of HD + and H 2 + . By comprehensive analysis, the efficacy of the two different types of synthesized two-color pulses (ω − 2ω and ω − 3ω) are analyzed with respect to one-color intense pulses in terms of controlling the probability modulation and electron localization asymmetry and compared with previous theoretical calculations and experimental findings. Through the detailed investigation, we have addressed which one is the major controlling knob to have better electron localization as well as probability modulation.

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Strong Laser Field-Driven Coupled Electron–Nuclear Dynamics: Quantum vs Classical Description

Cited by 3 publications

References 94 publications

Virtual Special Issue on Attosecond Chemistry

Virtual Special Issue on Attosecond Chemistry

Attosecond Probing of Nuclear Vibrations in the D₂⁺ and HeH⁺ Molecular Ions

Efficient Control of Electron Localization and Probability Modulation with Synthesized Two-Color Intense Laser Pulses

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Strong Laser Field-Driven Coupled Electron–Nuclear Dynamics: Quantum vs Classical Description

Cited by 3 publications

References 94 publications

Virtual Special Issue on Attosecond Chemistry

Virtual Special Issue on Attosecond Chemistry

Attosecond Probing of Nuclear Vibrations in the D2+ and HeH+ Molecular Ions

Efficient Control of Electron Localization and Probability Modulation with Synthesized Two-Color Intense Laser Pulses

Contact Info

Product

Resources

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Attosecond Probing of Nuclear Vibrations in the D₂⁺ and HeH⁺ Molecular Ions