Laser-driven direct quantum control of nuclear excitations

Ian Wong; Andreea Grigoriu; Jonathan Roslund; Tak San Ho; Herschel Albert Rabitz

doi:10.1103/PhysRevA.84.053429

Laser-driven direct quantum control of nuclear excitations

Ian Wong, Andreea Grigoriu, Jonathan Roslund, Tak San Ho, Herschel Albert Rabitz

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

The possibility of controlled direct laser-nuclear excitations is considered from a quantum control perspective. The controllability of laser-driven electric dipole and magnetic dipole transitions among pure nuclear states is analyzed. Within a set of realistic and general conditions, atomic nuclei are demonstrated to possess full state controllability. Additionally, an analysis of the nuclear state excitation probability as a function of the laser control field is conducted. This control landscape is shown to possess a generic topology, which has important physical consequences for achieving optimal nuclear state excitation with laser fields. Last, an assessment is given of the technological challenges that need to be considered when implementing direct nuclear control in the laboratory.

Original language	English (US)
Article number	053429
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	84
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevA.84.053429
State	Published - Nov 23 2011

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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10.1103/PhysRevA.84.053429

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title = "Laser-driven direct quantum control of nuclear excitations",

abstract = "The possibility of controlled direct laser-nuclear excitations is considered from a quantum control perspective. The controllability of laser-driven electric dipole and magnetic dipole transitions among pure nuclear states is analyzed. Within a set of realistic and general conditions, atomic nuclei are demonstrated to possess full state controllability. Additionally, an analysis of the nuclear state excitation probability as a function of the laser control field is conducted. This control landscape is shown to possess a generic topology, which has important physical consequences for achieving optimal nuclear state excitation with laser fields. Last, an assessment is given of the technological challenges that need to be considered when implementing direct nuclear control in the laboratory.",

author = "Ian Wong and Andreea Grigoriu and Jonathan Roslund and Ho, {Tak San} and Rabitz, {Herschel Albert}",

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AU - Wong, Ian

AU - Grigoriu, Andreea

AU - Roslund, Jonathan

AU - Ho, Tak San

AU - Rabitz, Herschel Albert

PY - 2011/11/23

Y1 - 2011/11/23

N2 - The possibility of controlled direct laser-nuclear excitations is considered from a quantum control perspective. The controllability of laser-driven electric dipole and magnetic dipole transitions among pure nuclear states is analyzed. Within a set of realistic and general conditions, atomic nuclei are demonstrated to possess full state controllability. Additionally, an analysis of the nuclear state excitation probability as a function of the laser control field is conducted. This control landscape is shown to possess a generic topology, which has important physical consequences for achieving optimal nuclear state excitation with laser fields. Last, an assessment is given of the technological challenges that need to be considered when implementing direct nuclear control in the laboratory.

AB - The possibility of controlled direct laser-nuclear excitations is considered from a quantum control perspective. The controllability of laser-driven electric dipole and magnetic dipole transitions among pure nuclear states is analyzed. Within a set of realistic and general conditions, atomic nuclei are demonstrated to possess full state controllability. Additionally, an analysis of the nuclear state excitation probability as a function of the laser control field is conducted. This control landscape is shown to possess a generic topology, which has important physical consequences for achieving optimal nuclear state excitation with laser fields. Last, an assessment is given of the technological challenges that need to be considered when implementing direct nuclear control in the laboratory.

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Laser-driven direct quantum control of nuclear excitations

Abstract

All Science Journal Classification (ASJC) codes

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