Optimal molecular alignment and orientation through rotational ladder climbing

Salomon, Julien; Dion, Claude M.; Turinici, Gabriel

doi:10.1063/1.2049270

Cited by 84 publications

(81 citation statements)

References 57 publications

(91 reference statements)

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“…Given a target value ε of the figure of merit, we measure the computational time necessary to obtain it. In the numerical computation, we use ε = 0.3, while the optimum has been numerically estimated as 0.2909 [42]. The values of the figure of merit are plotted in Fig.…”

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

“…Molecular orientation [33,34] is nowadays a wellestablished topic both from the experimental [35,36] and theoretical points of views [37][38][39][40][41]. Different optimal control analyses have been made on this quantum system [42][43][44][45].…”

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

“…We refer the reader to Ref. [42] for details on the numerical implementation of this control problem. The α parameter is chosen as a time-dependent function of the form 10 5 ( t − T /2 T /2 ) 6 + 10 4 in order to design a control field which is experimentally relevant [42].…”

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

“…[42] for details on the numerical implementation of this control problem. The α parameter is chosen as a time-dependent function of the form 10 5 ( t − T /2 T /2 ) 6 + 10 4 in order to design a control field which is experimentally relevant [42]. The target state is the eigenvector of the observable cos θ with the maximum eigenvalue in the subspace such that j ≤ 4 [39,46].…”

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

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Fully efficient time-parallelized quantum optimal control algorithm

et al. 2016

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We present a time-parallelization method that enables to accelerate the computation of quantum optimal control algorithms. We show that this approach is approximately fully efficient when based on a gradient method as optimization solver: the computational time is approximately divided by the number of available processors. The control of spin systems, molecular orientation and BoseEinstein condensates are used as illustrative examples to highlight the wide range of application of this numerical scheme.

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Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

Section: B Optimal Control Of Molecular Orientationmentioning

confidence: 99%

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Fully efficient time-parallelized quantum optimal control algorithm

et al. 2016

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“…OCT simulations have successfully controlled a variety of objectives, including state preparation [2,6,7], molecular isomerization [8][9][10][11][12], dissociation [13][14][15][16], and orientation/alignment [17][18][19]. OCE using ultrafast tailored laser pulses have achieved control over many processes including state preparation [20,21], selective molecular dissociation [22][23][24], generation of high order optical harmonics [25][26][27], and energy transfer and isomerization in large biomolecules [28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Exploring quantum control landscapes: Topology, features, and optimization scaling

2011

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Quantum optimal control experiments and simulations have successfully manipulated the dynamics of systems ranging from atoms to biomolecules. Surprisingly, these collective works indicate that the effort (i.e., the number of algorithmic iterations) required to find an optimal control field appears to be essentially invariant to the complexity of the system. The present work explores this matter in a series of systematic optimizations of the state-to-state transition probability on model quantum systems with the number of states N ranging from 5 through 100. The optimizations occur over a landscape defined by the transition probability as a function of the control field. Previous theoretical studies on the topology of quantum control landscapes established that they should be free of sub-optimal traps under reasonable physical conditions. The simulations in this work include nearly 5000 individual optimization test cases, all of which confirm this prediction by fully achieving optimal population transfer of at least 99.9% upon careful attention to numerical procedures to ensure that the controls are free of constraints. Collectively, the simulation results additionally show invariance of required search effort to system dimension N . This behavior is rationalized in terms of the structural features of the underlying control landscape. The very attractive observed scaling with system complexity may be understood by considering the distance traveled on the control landscape during a search and the magnitude of the control landscape slope. Exceptions to this favorable scaling behavior can arise when the initial control field fluence is too large or when the target final state recedes from the initial state as N increases.

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