Perturbative and nonperturbative photoionization of H2 and H2O using the molecular R-matrix-with-time method

Jakub Benda; Jimena Gorfinkiel; Zdenek Masin; Gregory Armstrong; Andrew Brown; Daniel Clarke; Hugo Van Der Hart; Jack Wragg

doi:10.1103/PhysRevA.102.052826

Perturbative and nonperturbative photoionization of H2 and H2O using the molecular R-matrix-with-time method

Jakub Benda, Jimena Gorfinkiel, Zdenek Masin, Gregory Armstrong, Andrew Brown, Daniel Clarke, Hugo Van Der Hart, Jack Wragg

School of Mathematics and Physics

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

4 Citations (Scopus)

160 Downloads (Pure)

Abstract

The ab initio R-matrix with time method has recently been extended to allow simulation of fully nonperturbative multielectron processes in molecules driven by ultrashort arbitrarily polarized strong laser fields. Here we demonstrate the accuracy and capabilities of the current implementation of the method for two targets: We study single-photon and multiphoton ionization of H2 and one-photon and strong-field ionization of H2O and compare the results to available experimental and theoretical data as well as our own time-independent R-matrix calculations. We obtain a highly accurate description of total and state-to-state single-photon ionization of H2O and, using a simplified coupled-channel model, we show that state coupling is essential to obtain qualitatively correct results and that its importance as a function of laser intensity changes. We find that electron correlation plays a more important role at low intensities (up to approximately 50 TW/cm2)

Original language	English
Journal	Physical Review A (Atomic, Molecular, and Optical Physics)
Volume	102
Issue number	052826
DOIs	https://doi.org/10.1103/PhysRevA.102.052826
Publication status	Published - 23 Nov 2020

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10.1103/PhysRevA.102.052826Licence: Unspecified

Perturbative and nonperturbative photoionization of H2 and H2O using the molecular R-matrix-with-time method
©2020 American Physical Society. This work is made available online in accordance with the publisher’s policies. Please refer to any applicable terms of use of the publisher.
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2 Active

R1066TCP: UK Atomic, Molecular and Optical physics R-matrix consortium (UK AMOR)
Brown, A.
18/06/2019 → …
Project: Research
R1728TCP: R-matrix Suites for Multielectron Attosecond Dynamics in Atoms and Molecules Irradiated by Arbitrarily Polarised Light
Van Der Hart, H. & Brown, A.
08/05/2017 → …
Project: Research

4 Citations
1 Article
1 Software

RMT: R-matrix with time-dependence. Solving the semi-relativistic, time-dependent Schrodinger equation for general, multi-electron atoms and molecules in intense, ultrashort, arbitrarily polarized laser pulses
Brown, A., Armstrong, G., Benda, J., Clarke, D., Wragg, J., Hamilton, K., Masin, Z., Gorfinkiel, J. & Van Der Hart, H., 01 May 2020, In: Computer Physics Communications. 250, 22 p., 107062.
Research output: Contribution to journal › Article › peer-review

Open Access
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17 Citations (Scopus)

225 Downloads (Pure)
The R-matrix with time dependence (RMT) code
Brown, A., Van Der Hart, H., Armstrong, G., Wragg, J., Clarke, D., Gorfinkiel, J., Benda, J. & Masin, Z., 11 Nov 2019
Research output: Non-textual form › Software

Cite this

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title = "Perturbative and nonperturbative photoionization of H2 and H2O using the molecular R-matrix-with-time method",

abstract = "The ab initio R-matrix with time method has recently been extended to allow simulation of fully nonperturbative multielectron processes in molecules driven by ultrashort arbitrarily polarized strong laser fields. Here we demonstrate the accuracy and capabilities of the current implementation of the method for two targets: We study single-photon and multiphoton ionization of H2 and one-photon and strong-field ionization of H2O and compare the results to available experimental and theoretical data as well as our own time-independent R-matrix calculations. We obtain a highly accurate description of total and state-to-state single-photon ionization of H2O and, using a simplified coupled-channel model, we show that state coupling is essential to obtain qualitatively correct results and that its importance as a function of laser intensity changes. We find that electron correlation plays a more important role at low intensities (up to approximately 50 TW/cm2)",

author = "Jakub Benda and Jimena Gorfinkiel and Zdenek Masin and Gregory Armstrong and Andrew Brown and Daniel Clarke and {Van Der Hart}, Hugo and Jack Wragg",

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T1 - Perturbative and nonperturbative photoionization of H2 and H2O using the molecular R-matrix-with-time method

AU - Benda, Jakub

AU - Gorfinkiel, Jimena

AU - Masin, Zdenek

AU - Armstrong, Gregory

AU - Brown, Andrew

AU - Clarke, Daniel

AU - Van Der Hart, Hugo

AU - Wragg, Jack

PY - 2020/11/23

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N2 - The ab initio R-matrix with time method has recently been extended to allow simulation of fully nonperturbative multielectron processes in molecules driven by ultrashort arbitrarily polarized strong laser fields. Here we demonstrate the accuracy and capabilities of the current implementation of the method for two targets: We study single-photon and multiphoton ionization of H2 and one-photon and strong-field ionization of H2O and compare the results to available experimental and theoretical data as well as our own time-independent R-matrix calculations. We obtain a highly accurate description of total and state-to-state single-photon ionization of H2O and, using a simplified coupled-channel model, we show that state coupling is essential to obtain qualitatively correct results and that its importance as a function of laser intensity changes. We find that electron correlation plays a more important role at low intensities (up to approximately 50 TW/cm2)

AB - The ab initio R-matrix with time method has recently been extended to allow simulation of fully nonperturbative multielectron processes in molecules driven by ultrashort arbitrarily polarized strong laser fields. Here we demonstrate the accuracy and capabilities of the current implementation of the method for two targets: We study single-photon and multiphoton ionization of H2 and one-photon and strong-field ionization of H2O and compare the results to available experimental and theoretical data as well as our own time-independent R-matrix calculations. We obtain a highly accurate description of total and state-to-state single-photon ionization of H2O and, using a simplified coupled-channel model, we show that state coupling is essential to obtain qualitatively correct results and that its importance as a function of laser intensity changes. We find that electron correlation plays a more important role at low intensities (up to approximately 50 TW/cm2)

U2 - 10.1103/PhysRevA.102.052826

DO - 10.1103/PhysRevA.102.052826

M3 - Article

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

JF - Physical Review A (Atomic, Molecular, and Optical Physics)

SN - 1050-2947

IS - 052826

ER -

Perturbative and nonperturbative photoionization of H2 and H2O using the molecular R-matrix-with-time method

Abstract

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Projects

R1066TCP: UK Atomic, Molecular and Optical physics R-matrix consortium (UK AMOR)

R1728TCP: R-matrix Suites for Multielectron Attosecond Dynamics in Atoms and Molecules Irradiated by Arbitrarily Polarised Light

Research output

RMT: R-matrix with time-dependence. Solving the semi-relativistic, time-dependent Schrodinger equation for general, multi-electron atoms and molecules in intense, ultrashort, arbitrarily polarized laser pulses

The R-matrix with time dependence (RMT) code

Cite this