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Autores principales: Ishii, Reon, Namba, Tomotaro, Katsuki, Hiroyuki, Ohmori, Kenji, Ohtsuki, Yukiyoshi
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2310.16440
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author Ishii, Reon
Namba, Tomotaro
Katsuki, Hiroyuki
Ohmori, Kenji
Ohtsuki, Yukiyoshi
author_facet Ishii, Reon
Namba, Tomotaro
Katsuki, Hiroyuki
Ohmori, Kenji
Ohtsuki, Yukiyoshi
contents On the basis of optimal control theory, we numerically study how to optimally manipulate molecular vibrational dynamics by using cycle-averaged polarizability interactions induced by mildly intense non-resonant laser (NR) pulses. As the essential elements to be controlled are the probability amplitudes, namely, the populations and the relative phases of the vibrational eigenstates, we consider three fundamental control objectives: selective population transfer, wave packet shaping that requires both population control and relative-phase control, and wave packet deformation suppression that solely requires relative-phase control while avoiding population redistribution. The non-trivial control of wave packet deformation suppression is an extension of our previous study on wave packet spreading suppression. Focusing on the vibrational dynamics in the B state of I2 as a case study, we adopt optimal control simulations and model analyses under the impulsive excitation approximation to systematically examine how to achieve the control objectives with shaped NR pulses. Optimal solutions are always given by NR pulse trains, in which each pulse interval and each pulse intensity are adjusted to cooperate with the vibrational dynamics to effectively utilize the quantum interferences to realize the control objectives with high probability.
format Preprint
id arxiv_https___arxiv_org_abs_2310_16440
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Optimal control for manipulating vibrational wave packets through polarizability interactions induced by non-resonant laser pulses
Ishii, Reon
Namba, Tomotaro
Katsuki, Hiroyuki
Ohmori, Kenji
Ohtsuki, Yukiyoshi
Quantum Physics
On the basis of optimal control theory, we numerically study how to optimally manipulate molecular vibrational dynamics by using cycle-averaged polarizability interactions induced by mildly intense non-resonant laser (NR) pulses. As the essential elements to be controlled are the probability amplitudes, namely, the populations and the relative phases of the vibrational eigenstates, we consider three fundamental control objectives: selective population transfer, wave packet shaping that requires both population control and relative-phase control, and wave packet deformation suppression that solely requires relative-phase control while avoiding population redistribution. The non-trivial control of wave packet deformation suppression is an extension of our previous study on wave packet spreading suppression. Focusing on the vibrational dynamics in the B state of I2 as a case study, we adopt optimal control simulations and model analyses under the impulsive excitation approximation to systematically examine how to achieve the control objectives with shaped NR pulses. Optimal solutions are always given by NR pulse trains, in which each pulse interval and each pulse intensity are adjusted to cooperate with the vibrational dynamics to effectively utilize the quantum interferences to realize the control objectives with high probability.
title Optimal control for manipulating vibrational wave packets through polarizability interactions induced by non-resonant laser pulses
topic Quantum Physics
url https://arxiv.org/abs/2310.16440