Dissecting Strong-Field Excitation Dynamics with Atomic-Momentum Spectroscopy

A. W. Bray; A. W. Bray; U. Eichmann; S. Patchkovskii

doi:10.1103/PhysRevLett.124.233202

Dissecting Strong-Field Excitation Dynamics with Atomic-Momentum Spectroscopy

A. W. Bray, A. W. Bray, U. Eichmann, S. Patchkovskii

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

8 Citations (Scopus)

Abstract

Observation of internal quantum dynamics relies on correlations between the system being observed and the measurement apparatus. We propose using the c.m. degrees of freedom of atoms and molecules as a "built-in"monitoring device for observing their internal dynamics in nonperturbative laser fields. We illustrate the idea on the simplest model system-the hydrogen atom in an intense, tightly focused infrared laser beam. To this end, we develop a numerically tractable, quantum-mechanical treatment of correlations between internal and c.m. dynamics. We show that the transverse momentum records the time excited states experience the field, allowing femtosecond reconstruction of the strong-field excitation process. The ground state becomes weak-field seeking, an unambiguous and long sought-for signature of the Kramers-Henneberger regime.

Original language	English
Article number	233202
Journal	Physical Review Letters
Volume	124
Issue number	23
DOIs	https://doi.org/10.1103/PhysRevLett.124.233202
Publication status	Published - 12 Jun 2020

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abstract = "Observation of internal quantum dynamics relies on correlations between the system being observed and the measurement apparatus. We propose using the c.m. degrees of freedom of atoms and molecules as a {"}built-in{"}monitoring device for observing their internal dynamics in nonperturbative laser fields. We illustrate the idea on the simplest model system-the hydrogen atom in an intense, tightly focused infrared laser beam. To this end, we develop a numerically tractable, quantum-mechanical treatment of correlations between internal and c.m. dynamics. We show that the transverse momentum records the time excited states experience the field, allowing femtosecond reconstruction of the strong-field excitation process. The ground state becomes weak-field seeking, an unambiguous and long sought-for signature of the Kramers-Henneberger regime.",

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AB - Observation of internal quantum dynamics relies on correlations between the system being observed and the measurement apparatus. We propose using the c.m. degrees of freedom of atoms and molecules as a "built-in"monitoring device for observing their internal dynamics in nonperturbative laser fields. We illustrate the idea on the simplest model system-the hydrogen atom in an intense, tightly focused infrared laser beam. To this end, we develop a numerically tractable, quantum-mechanical treatment of correlations between internal and c.m. dynamics. We show that the transverse momentum records the time excited states experience the field, allowing femtosecond reconstruction of the strong-field excitation process. The ground state becomes weak-field seeking, an unambiguous and long sought-for signature of the Kramers-Henneberger regime.

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Dissecting Strong-Field Excitation Dynamics with Atomic-Momentum Spectroscopy

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