Extracting Information from Adaptive Control Experiments

White, J. L.; Carroll, Elizabeth C.; Spears, Kenneth G.; Sension, Roseanne J.

doi:10.1002/ijch.201100106

Cited by 3 publications

(2 citation statements)

References 81 publications

(130 reference statements)

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“…Several control schemes have been described and implemented. − Adaptive approaches (often using a learning algorithm in combination with a pulse shaper) have been used to control molecular dynamics. Interpreting the mechanism underlying control in closed loop experiments is challenging although possible with the aid of ab initio electronic structure and quantum dynamics calculations. − The complementary approach is to implement control with a particular mechanism in mind, based on a detailed understanding of the molecular potential energy surfaces involved. The work described in this manuscript belongs to the latter category and uses a strong IR pulse to change the evolution of a nuclear wave packet, whereas key parameters of the control pulse (timing, intensity and duration) are systematically varied.…”

Section: Introductionmentioning

confidence: 99%

Control of Nuclear Dynamics with Strong Ultrashort Laser Pulses

et al. 2012

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We demonstrate how the evolution of a bound vibrational wave packet can be controlled by a strong field laser pulse. We consider two different control schemes within the same molecule (CH(2)BrI): reshaping of the wave packet via strong field population transfer ("hole burning"), and redirecting its trajectory by dressing the potential energy surface on which the wave packet evolves ("photon locking"). Our measurements are compared with calculations using wave packet propagation on ab initio potential energy surfaces.

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Section: Introductionmentioning

confidence: 99%

Control of Nuclear Dynamics with Strong Ultrashort Laser Pulses

et al. 2012

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“…Over the past decade, photo-fragmentation control has been illustrated for quite a few systems through the detection and interpretation of patterns in molecular fragmentation using an adaptive approach of ultrafast laser pulse shaping techniques [1-7]. Often, however, the final pulse shapes in such adaptive approaches were not found to be globally optimized [2,3,8,9].…”

Section: Introductionmentioning

confidence: 99%

Controlling the femtosecond laser-driven transformation of dicyclopentadiene into cyclopentadiene

Goswami

Das

2013

Chemical Physics Letters

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Graphical abstractControl of a femtosecond chemical transformation of dicyclopentadiene into cyclopentadiene in a supersonic molecular beam is achieved by using linearly chirped frequency modulated pulses, indicating that the phase structure of the laser pulse plays an important role in determining the reaction outcome.Highlights► Reporting the timescale of a femtosecond decylization reaction. ► Controlling the decyclization reaction through femtosecond chirped pulses. ► Distinguishing the reaction process from the fragment ionization process.

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Adaptive strong-field control of vibrational population in NO2+

Voznyuk

Jochim

Zohrabi

et al. 2019

The Journal of Chemical Physics

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An adaptive closed-loop system employing coincidence time-of-flight feedback is used to determine the optimal pulse shapes for manipulating the branching ratio of NO dications following double ionization by an intense laser pulse. Selection between the long-lived NO2+ and the dissociative N+ + O+ final states requires control of the vibrational population distribution in the transient NO2+. The ability to both suppress and enhance NO2+ relative to N+ + O+ is observed, with the effectiveness of shaped pulses surpassing near Fourier transform-limited pulses by about an order of magnitude in each direction, depending on the pulse energy. The control is subsequently investigated using velocity map imaging, identifying plausible dissociation pathways leading to N+ + O+. Combining the information about the N+ + O+ dissociation with a well-defined control objective supports the conclusion that the primary control mechanism involves selectively populating long-lived NO2+ vibrational states.

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Extracting Information from Adaptive Control Experiments

Cited by 3 publications

References 81 publications

Control of Nuclear Dynamics with Strong Ultrashort Laser Pulses

Control of Nuclear Dynamics with Strong Ultrashort Laser Pulses

Controlling the femtosecond laser-driven transformation of dicyclopentadiene into cyclopentadiene

Adaptive strong-field control of vibrational population in NO2+

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