H
Herschel Rabitz
Researcher at Princeton University
Publications - 1144
Citations - 39496
Herschel Rabitz is an academic researcher from Princeton University. The author has contributed to research in topics: Optimal control & Quantum dynamics. The author has an hindex of 84, co-authored 1127 publications receiving 36941 citations. Previous affiliations of Herschel Rabitz include United Nations Industrial Development Organization & Max Planck Society.
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Teaching lasers to control molecules.
TL;DR: This work simulates an apparatus that learns to excite specified rotational states in a diatomic molecule and uses a learning procedure to direct the production of pulses based on fitness'' information provided by a laboratory measurement device.
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Whither the future of controlling quantum phenomena
TL;DR: The preview of the field presented here suggests that important advances in the control of molecules and the capability of learning about molecular interactions may be reached through the application of emerging theoretical concepts and laboratory technologies.
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Coherent control of quantum dynamics: the dream is alive.
TL;DR: Current experimental and theoretical progress toward the goal of controlling quantum dynamics is summarized and the introduction of engineering control concepts has put the required theoretical framework on a rigorous foundation.
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General foundations of high-dimensional model representations
Herschel Rabitz,Ömer F. Aliş +1 more
TL;DR: In this article, a family of multivariate representations is introduced to capture the input-output relationships of high-dimensional physical systems with many input variables and a systematic mapping procedure between the inputs and outputs is prescribed to reveal the hierarchy of correlations amongst the input variables.
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Selective Bond Dissociation and Rearrangement with Optimally Tailored, Strong-Field Laser Pulses
TL;DR: Strong-field control appears to have generic applicability for manipulating molecular reactivity because the tailored intense laser fields can dynamically Stark shift many excited states into resonance, and consequently, the method is not confined by resonant spectral restrictions found in the perturbative (weak-field) regime.