Optimal control of nonlinear classical systems with application to unimolecular dissociation reactions and chaotic potentials
- 1 October 1991
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 44 (8), 5224-5238
- https://doi.org/10.1103/physreva.44.5224
Abstract
In this paper we apply optimal control theory to nonlinear classical systems for the design of electric fields that interact with the systems so that an ensemble of classical trajectories are manipulated in some desired way. Control of selective unimolecular bond dissociation is demonstrated in the classical regime on a model linear triatomic molecule with spreading of the ensemble of trajectories held to a minimum for closer agreement between quantum and classical mechanics. Control was also demonstrated over trajectories in a highly chaotic two-dimensional system. It was found in the cases studied that a high degree of control was attained in situations where the dynamics are chaotic in the absence of a controlling field.Keywords
This publication has 22 references indexed in Scilit:
- Optimal control of bond selectivity in unimolecular reactionsComputer Physics Communications, 1991
- Optical control of molecular motion with robustness and application to vinylidene fluorideJournal of the Optical Society of America B, 1990
- Optimal design of external fields for controlling molecular motion: application to rotationJournal of Molecular Structure, 1990
- Application of optimal control theory for selective vibrational excitation in molecules modeled as harmonic physical systemsJournal of Mathematical Physics, 1990
- Quantum mechanical optimal control of physical observables in microsystemsThe Journal of Chemical Physics, 1990
- Selective excitation in harmonic molecular systems by optimally designed fieldsChemical Physics, 1989
- Optimal control of selective vibrational excitation in harmonic linear chain moleculesThe Journal of Chemical Physics, 1988
- Optimal control of quantum-mechanical systems: Existence, numerical approximation, and applicationsPhysical Review A, 1988
- Coherent pulse sequence induced control of selectivity of reactions. Exact quantum-mechanical calculationsJournal of the Chemical Society, Faraday Transactions 2: Molecular and Chemical Physics, 1986
- Control of selectivity of chemical reaction via control of wave packet evolutionThe Journal of Chemical Physics, 1985