Kinematically complete experimental study of Compton scattering at helium atoms near the threshold

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Max Kircher
  • Florian Trinter
  • Sven Grundmann
  • Isabel Vela-Perez
  • Simon Brennecke
  • Nicolas Eicke
  • Jonas Rist
  • Sebastian Eckart
  • Salim Houamer
  • Ochbadrakh Chuluunbaatar
  • Yuri V. Popov
  • Igor P. Volobuev
  • Kai Bagschik
  • M. Novella Piancastelli
  • Manfred Lein
  • Till Jahnke
  • Markus S. Schöffler
  • Reinhard Dörner

Organisationseinheiten

Externe Organisationen

  • Goethe-Universität Frankfurt am Main
  • Deutsches Elektronen-Synchrotron (DESY)
  • Fritz-Haber-Institut der Max-Planck-Gesellschaft
  • Universite Ferhat Abbas
  • Joint Institute for Nuclear Research (JINR)
  • Mongolian Academy of Sciences
  • Peoples' Friendship University of Russia (RUDN)
  • Lomonosov Moscow State University
  • Universite Paris 6
  • Uppsala University
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)756-760
Seitenumfang5
FachzeitschriftNature Physics
Jahrgang16
Ausgabenummer7
Frühes Online-Datum13 Apr. 2020
PublikationsstatusVeröffentlicht - Juli 2020

Abstract

Compton scattering is one of the fundamental interaction processes of light with matter. When discovered1, it was described as a billiard-type collision of a photon ‘kicking’ a quasi-free electron. With decreasing photon energy, the maximum possible momentum transfer becomes so small that the corresponding energy falls below the binding energy of the electron. In this regime, ionization by Compton scattering becomes an intriguing quantum phenomenon. Here, we report on a kinematically complete experiment studying Compton scattering off helium atoms in that regime. We determine the momentum correlations of the electron, the recoiling ion and the scattered photon in a coincidence experiment based on cold target recoil ion momentum spectroscopy, finding that electrons are not only emitted in the direction of the momentum transfer, but that there is a second peak of ejection to the backward direction. This finding links Compton scattering to processes such as ionization by ultrashort optical pulses2, electron impact ionization3,4, ion impact ionization5,6 and neutron scattering7, where similar momentum patterns occur.

ASJC Scopus Sachgebiete

Zitieren

Kinematically complete experimental study of Compton scattering at helium atoms near the threshold. / Kircher, Max; Trinter, Florian; Grundmann, Sven et al.
in: Nature Physics, Jahrgang 16, Nr. 7, 07.2020, S. 756-760.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Kircher, M, Trinter, F, Grundmann, S, Vela-Perez, I, Brennecke, S, Eicke, N, Rist, J, Eckart, S, Houamer, S, Chuluunbaatar, O, Popov, YV, Volobuev, IP, Bagschik, K, Piancastelli, MN, Lein, M, Jahnke, T, Schöffler, MS & Dörner, R 2020, 'Kinematically complete experimental study of Compton scattering at helium atoms near the threshold', Nature Physics, Jg. 16, Nr. 7, S. 756-760. https://doi.org/10.1038/s41567-020-0880-2
Kircher, M., Trinter, F., Grundmann, S., Vela-Perez, I., Brennecke, S., Eicke, N., Rist, J., Eckart, S., Houamer, S., Chuluunbaatar, O., Popov, Y. V., Volobuev, I. P., Bagschik, K., Piancastelli, M. N., Lein, M., Jahnke, T., Schöffler, M. S., & Dörner, R. (2020). Kinematically complete experimental study of Compton scattering at helium atoms near the threshold. Nature Physics, 16(7), 756-760. https://doi.org/10.1038/s41567-020-0880-2
Kircher M, Trinter F, Grundmann S, Vela-Perez I, Brennecke S, Eicke N et al. Kinematically complete experimental study of Compton scattering at helium atoms near the threshold. Nature Physics. 2020 Jul;16(7):756-760. Epub 2020 Apr 13. doi: 10.1038/s41567-020-0880-2
Kircher, Max ; Trinter, Florian ; Grundmann, Sven et al. / Kinematically complete experimental study of Compton scattering at helium atoms near the threshold. in: Nature Physics. 2020 ; Jahrgang 16, Nr. 7. S. 756-760.
Download
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abstract = "Compton scattering is one of the fundamental interaction processes of light with matter. When discovered1, it was described as a billiard-type collision of a photon {\textquoteleft}kicking{\textquoteright} a quasi-free electron. With decreasing photon energy, the maximum possible momentum transfer becomes so small that the corresponding energy falls below the binding energy of the electron. In this regime, ionization by Compton scattering becomes an intriguing quantum phenomenon. Here, we report on a kinematically complete experiment studying Compton scattering off helium atoms in that regime. We determine the momentum correlations of the electron, the recoiling ion and the scattered photon in a coincidence experiment based on cold target recoil ion momentum spectroscopy, finding that electrons are not only emitted in the direction of the momentum transfer, but that there is a second peak of ejection to the backward direction. This finding links Compton scattering to processes such as ionization by ultrashort optical pulses2, electron impact ionization3,4, ion impact ionization5,6 and neutron scattering7, where similar momentum patterns occur.",
author = "Max Kircher and Florian Trinter and Sven Grundmann and Isabel Vela-Perez and Simon Brennecke and Nicolas Eicke and Jonas Rist and Sebastian Eckart and Salim Houamer and Ochbadrakh Chuluunbaatar and Popov, {Yuri V.} and Volobuev, {Igor P.} and Kai Bagschik and Piancastelli, {M. Novella} and Manfred Lein and Till Jahnke and Sch{\"o}ffler, {Markus S.} and Reinhard D{\"o}rner",
note = "Funding Information: This work was supported by DFG and BMBF. O.C. acknowledges support from the Hulubei-Meshcheryakov programme JINR-Romania and the RUDN University Program 5-100. Y.V.P. is grateful to the Russian Foundation of Basic Research (RFBR) for financial support under grant no. 19-02-00014a. S.H. thanks the Direction Generale de la Recherche Scientifique et du Developpement Technologique (DGRSDT-Algeria) for financial support. We are grateful to the staff of PETRA III for excellent support during the beam time. Calculations were performed on the Central Information and Computer Complex and heterogeneous computing platform HybriLIT through supercomputer {\textquoteleft}Govorun{\textquoteright} of JINR.",
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AU - Kircher, Max

AU - Trinter, Florian

AU - Grundmann, Sven

AU - Vela-Perez, Isabel

AU - Brennecke, Simon

AU - Eicke, Nicolas

AU - Rist, Jonas

AU - Eckart, Sebastian

AU - Houamer, Salim

AU - Chuluunbaatar, Ochbadrakh

AU - Popov, Yuri V.

AU - Volobuev, Igor P.

AU - Bagschik, Kai

AU - Piancastelli, M. Novella

AU - Lein, Manfred

AU - Jahnke, Till

AU - Schöffler, Markus S.

AU - Dörner, Reinhard

N1 - Funding Information: This work was supported by DFG and BMBF. O.C. acknowledges support from the Hulubei-Meshcheryakov programme JINR-Romania and the RUDN University Program 5-100. Y.V.P. is grateful to the Russian Foundation of Basic Research (RFBR) for financial support under grant no. 19-02-00014a. S.H. thanks the Direction Generale de la Recherche Scientifique et du Developpement Technologique (DGRSDT-Algeria) for financial support. We are grateful to the staff of PETRA III for excellent support during the beam time. Calculations were performed on the Central Information and Computer Complex and heterogeneous computing platform HybriLIT through supercomputer ‘Govorun’ of JINR.

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N2 - Compton scattering is one of the fundamental interaction processes of light with matter. When discovered1, it was described as a billiard-type collision of a photon ‘kicking’ a quasi-free electron. With decreasing photon energy, the maximum possible momentum transfer becomes so small that the corresponding energy falls below the binding energy of the electron. In this regime, ionization by Compton scattering becomes an intriguing quantum phenomenon. Here, we report on a kinematically complete experiment studying Compton scattering off helium atoms in that regime. We determine the momentum correlations of the electron, the recoiling ion and the scattered photon in a coincidence experiment based on cold target recoil ion momentum spectroscopy, finding that electrons are not only emitted in the direction of the momentum transfer, but that there is a second peak of ejection to the backward direction. This finding links Compton scattering to processes such as ionization by ultrashort optical pulses2, electron impact ionization3,4, ion impact ionization5,6 and neutron scattering7, where similar momentum patterns occur.

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