Applying artificial neural networks to coherent control experiments: A theoretical proof of concept

Thomas, Esben Folger; Henriksen, Niels Engholm

doi:10.1103/physreva.99.023422

Cited by 5 publications

(5 citation statements)

References 37 publications

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“…II. We note that the corresponding intensities are of the same order of magnitude as those considered in very recent theoretical work on laser-induced deracemization, neglecting effects of ionization [40][41][42].…”

Section: Resultssupporting

confidence: 63%

“…With this work we have initiated a study of torsional effects in strong-field ionization of molecules. We have investigated biphenyl and substituted biphenyl as illustrative examples motivated by the fact that torsional motion has been elucidated in alignment resolved experiments in such systems [36][37][38][39] and that these molecules have been explored theoretically in connection with laser-based protocols for laser-induced deracemization [40][41][42]. The determination of the molecular property related to the strong-field tunneling ionization process, the structure factor of the WFAT [43], was made possible by application of the newly implemented methodology [46] for the integral representation of WFAT [44] (see also Ref.…”

Section: Discussionmentioning

confidence: 99%

“…[36,37] or 3,5-difluoro-3 , 5 -dibromo-4 -cyanobiphenyl [38,39], to its mirror form by light-induced deracemization, thereby producing enantiomeric excess. More recently, the possibility for laser-induced enantiomeric conversion of DFDBrBPh based on dynamic Stark control was investigated theoretically [40,41], including considerations of possibilities associated with invoking of artificial neural networks [42]. In the latter theoretical studies, the intensities considered were up to tens of TW/cm 2 , but the role of ionization in the dynamics was not considered.…”

Section: Introductionmentioning

confidence: 99%

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Torsional effects in strong-field ionization of molecules

Dnestryan

Tolstikhin

Jensen

et al. 2019

Phys. Rev. Research

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We investigate how the ionization rate of molecules consisting of a pair of phenyl rings depends on the torsional dihedral angle between these two rings. We consider different orientations of the molecules with respect to the external field direction and find differences in the rates in biphenyl and substituted biphenyl. The evaluation of the rates is made possible by application of the integral representation of the weak-field asymptotic theory for tunneling ionization. We report a strong variation of the ionization rates with dihedral angle with contributions from several orbitals and a large difference between biphenyl and substituted biphenyl related to the permanent dipole of the latter system.

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Section: Resultssupporting

confidence: 63%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Torsional effects in strong-field ionization of molecules

Dnestryan

Tolstikhin

Jensen

et al. 2019

Phys. Rev. Research

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“…There have been many theoretical reports considering such dynamical coupling between torsion and rotation in BP derivatives. ,,− For precisely tracking the time evolution of the system, it is required to solve four-dimensional (4D) time-dependent Schrödinger equations (TDSE) with one-dimensional (1D) + three-dimensional (3D) for vibrational and rotational degrees of freedom, respectively. − Obviously, such a full quantum calculation is too demanding, as sufficient numbers of basis functions are so large, in particular, to expand WPs for molecular rotation . Some previous studies have adopted reduced dimensional calculations, in which molecular rotation is completely ignored or regarded as a 1D motion around the major principal axis. ,,− ,− These 2D (1D torsion + 1D rotation) approaches are appropriate for molecules prealigned by adiabatic alignment, as for the time-resolved CEI experiments. − However, in usual experimental conditions, the initial directional distribution of molecular ensembles is isotropic, as in the present case. Detailed comparisons of the experimental outcome with theoretical results are indispensable for a deeper understanding of the underlying physics.…”

Section: Introductionmentioning

confidence: 99%

Torsional Wave-Packet Dynamics in 2-Fluorobiphenyl Investigated by State-Selective Ionization-Detected Impulsive Stimulated Raman Spectroscopy

2023

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We report the creation and observation of vibrational wave packets pertinent to torsional motion in a biphenyl derivative in its electronic ground-state manifold. Adiabatically cooled molecular samples of 2-fluorobiphenyl were irradiated by intense nonresonant ultrashort laser pulses to drive impulsive stimulated Raman excitation of torsional motion. Spectral change due to the nonadiabatic vibrational excitation is probed in a state-selective manner using resonance-enhanced two-photon ionization through the S1 ← S0 electronic transition. The coherent nature of the excitation was exemplified by adopting irradiation with a pair of pump pulses: observed signals for excited torsional levels exhibit oscillatory variations against the mutual delay between the pump pulses due to wave-packet interference. By taking the Fourier transform of the time course of the signals, energy intervals among torsional levels with v = 0–3 were determined and utilized to calibrate a density functional theory (DFT)-calculated torsional potential-energy function. Time variation of populations in the excited torsional levels was assessed experimentally by measuring integrated intensities of the corresponding transitions while scanning the delay. Early time enhancement of the population (up to ∼2 ps) and gradual degradation of coherence (within ∼20 ps) appears. To explain the observed distinctive features, we developed a four-dimensional (4D) dynamical calculation in which one-dimensional (1D) quantum-mechanical propagation of the torsional motion was followed by solving the time-dependent Schrödinger equation, whereas three-dimensional (3D) molecular rotation was tracked by classical trajectory calculations. This hybrid approach enabled us to reproduce experimental results at a reasonable computational cost and provided a deeper insight into rotational effects on vibrational wave-packet dynamics.

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“…Our goal concerns the timely issue of optimizing control procedures for quantum systems strongly coupled to struc- * michele.desouter-lecomte@universite-paris-saclay.fr tured environments and leading to non-Markovian reduced dynamics. This requires implementing an optimization procedure of the parametric space among numerous available methods [17][18][19][20][21][22][23][24] with an efficient treatment of non-Markovian open systems [16,[25][26][27]. There are two main ways to account for the non-Markovianity reviewed for instance in reference [28].…”

Section: Introductionmentioning

confidence: 99%

Laser-controlled electronic symmetry breaking in a phenylene ethynylene dimer: Simulation by the hierarchical equations of motion and optimal control

et al. 2022

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The ability to prepare a specific superposition of electronic excited states leading to a transitory symmetry breaking of the electronic density in complex systems remains a challenging concern. We investigate how an initial coherence can be controlled by laser fields. The selected molecular system is a symmetric dimer of phenylene ethynylene presenting different interesting properties: two bright nearly degenerate excited states coupled through a conical intersection are addressable by orthogonal transition dipole moments and are well separated from neighboring states. Creating a superposed state with equal weights corresponds to a right or left electronic localization as in the double-well system followed by a transitory oscillation between the two wells. To ensure a spectral bandwidth typically smaller than 0.25 eV, the pulse duration is in the tens of femtoseconds range so that nuclear motion cannot be neglected. Optimal control theory (OCT) is applied with guess fields that effectively create the target coherence in the absence of dephasing due to the vibrational baths. We analyze the field reshaping proposed by the control and we further fit sequence of pulses on the optimal field. The overall result is efficient and robust disymmetry control over reasonable time scales of few tens of femtoseconds, exceeding the pulse duration. The monotonically convergent algorithm is combined with the hierarchical equations of motion (HEOM) able to treat strongly coupled non-Markovian dynamics. We also check the implementation of the combined OCT-HEOM approach in the tensor-train (TT) representation with propagation using the time dependent variational method.

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Applying artificial neural networks to coherent control experiments: A theoretical proof of concept

Cited by 5 publications

References 37 publications

Torsional effects in strong-field ionization of molecules

Torsional effects in strong-field ionization of molecules

Torsional Wave-Packet Dynamics in 2-Fluorobiphenyl Investigated by State-Selective Ionization-Detected Impulsive Stimulated Raman Spectroscopy

Laser-controlled electronic symmetry breaking in a phenylene ethynylene dimer: Simulation by the hierarchical equations of motion and optimal control

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