Numerical simulation of time delays in light-induced ionization

Jing Su; Hongcheng Ni; Andreas Becker; Agnieszka Jaroń-Becker

doi:10.1103/PhysRevA.87.033420

Numerical simulation of time delays in light-induced ionization

Jing Su^*
, Hongcheng Ni
, Andreas Becker
, Agnieszka Jaroń-Becker

^*Corresponding author for this work

University of Colorado Boulder

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

21 Scopus citations

Abstract

We apply a fundamental definition of time delay, as the difference between the time a particle spends within a finite region of a potential and the time a free particle spends in the same region, to determine results for photoionization of an electron by an extreme ultraviolet laser field using numerical simulations on a grid. Our numerical results are in good agreement with those of the Wigner-Smith time delay, obtained as the derivative of the phase shift of the scattering wave packet with respect to its energy, for the short-range Yukawa potential. In the case of the Coulomb potential we obtain time delays for any finite region, while - as expected - the results do not converge as the size of the region increases towards infinity. The impact of an ultrashort near-infrared probe pulse on the time delay introduced here is analyzed for both the Yukawa and the Coulomb potential and is found to be small for intensities below 1013 W/cm2.

Original language	English
Article number	033420
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	87
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevA.87.033420
State	Published - 27 Mar 2013
Externally published	Yes

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title = "Numerical simulation of time delays in light-induced ionization",

abstract = "We apply a fundamental definition of time delay, as the difference between the time a particle spends within a finite region of a potential and the time a free particle spends in the same region, to determine results for photoionization of an electron by an extreme ultraviolet laser field using numerical simulations on a grid. Our numerical results are in good agreement with those of the Wigner-Smith time delay, obtained as the derivative of the phase shift of the scattering wave packet with respect to its energy, for the short-range Yukawa potential. In the case of the Coulomb potential we obtain time delays for any finite region, while - as expected - the results do not converge as the size of the region increases towards infinity. The impact of an ultrashort near-infrared probe pulse on the time delay introduced here is analyzed for both the Yukawa and the Coulomb potential and is found to be small for intensities below 1013 W/cm2.",

author = "Jing Su and Hongcheng Ni and Andreas Becker and Agnieszka Jaro{\'n}-Becker",

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T1 - Numerical simulation of time delays in light-induced ionization

AU - Su, Jing

AU - Ni, Hongcheng

AU - Becker, Andreas

AU - Jaroń-Becker, Agnieszka

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Y1 - 2013/3/27

N2 - We apply a fundamental definition of time delay, as the difference between the time a particle spends within a finite region of a potential and the time a free particle spends in the same region, to determine results for photoionization of an electron by an extreme ultraviolet laser field using numerical simulations on a grid. Our numerical results are in good agreement with those of the Wigner-Smith time delay, obtained as the derivative of the phase shift of the scattering wave packet with respect to its energy, for the short-range Yukawa potential. In the case of the Coulomb potential we obtain time delays for any finite region, while - as expected - the results do not converge as the size of the region increases towards infinity. The impact of an ultrashort near-infrared probe pulse on the time delay introduced here is analyzed for both the Yukawa and the Coulomb potential and is found to be small for intensities below 1013 W/cm2.

AB - We apply a fundamental definition of time delay, as the difference between the time a particle spends within a finite region of a potential and the time a free particle spends in the same region, to determine results for photoionization of an electron by an extreme ultraviolet laser field using numerical simulations on a grid. Our numerical results are in good agreement with those of the Wigner-Smith time delay, obtained as the derivative of the phase shift of the scattering wave packet with respect to its energy, for the short-range Yukawa potential. In the case of the Coulomb potential we obtain time delays for any finite region, while - as expected - the results do not converge as the size of the region increases towards infinity. The impact of an ultrashort near-infrared probe pulse on the time delay introduced here is analyzed for both the Yukawa and the Coulomb potential and is found to be small for intensities below 1013 W/cm2.

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JO - Physical Review A - Atomic, Molecular, and Optical Physics

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Numerical simulation of time delays in light-induced ionization

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