Vacancies Decay: Results of Calculations



In this chapter, we collect and comment figures and tables, which present data, obtained in calculations of photoelectron satellite intensities and line shapes, intensities of Auger spectra, some line shapes of low-energy Auger lines, and radiation widths.


Configuration Interaction Spectroscopic Factor Radiation Width Auger Decay Configuration Interaction Method 
These keywords were added by machine and not by the authors. This process is experimental and the keywords may be updated as the learning algorithm improves.


  1. 6.1.
    Svensson S, Eriksson B, Martensson N, Wendin G, Gelius U (1988) Electron shake-up and correlation satellites and continuum shake-off distributions in X-ray photoelectron spectra of rare gas atoms. J Electron Spectrosc Relat Phenom 47:327–384Google Scholar
  2. 6.2.
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  3. 6.3.
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  4. 6.4.
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  5. 6.5.
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  6. 6.6.
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  7. 6.7.
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  9. 6.9.
    Pahler M, Caldwell CD, Schaphorst SJ, Krause MO (1993) Intrinsic line widths of neon 2s2p(1, 3 P)nl 2 L correlation satellites. J Phys B At Mol Opt Phys 26:1617–1625Google Scholar
  10. 6.10.
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  11. 6.11.
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  12. 6.12.
    Yarzhemsky VG, Reich T, Chernysheva LV, Streubel P, Szargan R (1996) Lineshape asymmetry parameters in X-ray photoelectron spectra J Electron Spectrosc Relat Phenom 77:15–24Google Scholar
  13. 6.13.
    Kelly HP (1975) K Auger rates calculated for Ne + . Phys Rev A 11:556–565Google Scholar
  14. 6.14.
    Tulkki J, Åberg T, Mäntykenttä A, Aksela H (1992) Relativistic multichannel calculation of the NeKLL and Ar L 2 M 2, 3 M 2, 3 Auger transition rates. Phys Rev A 43:1357–1366Google Scholar
  15. 6.15.
    Yarzhemsky VG, Sgamellotti A (2002) Auger rates of second row atoms calculated by many-body perturbation theory J Electron Spectrosc Relat Phenom 125:13–24Google Scholar
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    Bhalla CP (1973) Effect of configuration interaction of K-shell Auger spectrum of neon. Phys Lett A 44:103–104Google Scholar
  17. 6.17.
    Lohman B, Fritzsche S (1996) Intensities and angular distribution parameters for the KLL Auger transitions of atomic oxygen. J Phys B At Mol Opt Phys 29:5711–5723Google Scholar
  18. 6.18.
    Saha HP (1994) Theoretical studies of the K-shell Auger spectrum of atomic oxygen. Phys Rev A 49:894–898Google Scholar
  19. 6.19.
    Petrini D, de Araujo FX (1994) Auger process following 1s-photoionization: OIII lines. Astron Astrophys 282:315–317Google Scholar
  20. 6.20.
    Caldwell CD, Krause MO (1993) K-shell Auger spectrum of atomic oxygen. Phys Rev A 47:R759–R762Google Scholar
  21. 6.21.
    Kilin VA, Lazarev DA (1998) Double Auger decay of 3d vacancy in krypton. Russian Phys J 4(10):1001–1009Google Scholar
  22. 6.22.
    Ehresmann A, Kilin VA, Chernysheva LV, Schmoranzer H, Amusia MYa, Schartner K-H (1993) Three-electron radiative transitions. J Phys B At Mol Opt Phys 26:L97–L102Google Scholar
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    Kilin VA (2004) Correlation effects in multiple ionization processes. Dr. Sc.Thesis, Tomsk State University (in Russian)Google Scholar
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    Ehresmann A, Kilin VA, Schmoranzer H, Schartner K-H, Amusia MYa (1995) Assignment of new fluorescence lines from Kr III 4p36s5d states observed after excitation of the Kr I 3d 5 ∕ 2 95p-resonance. J Phys B At Mol Opt Phys 28:965–977Google Scholar
  25. 6.25.
    Amusia MYa, Kilin VA, Ehresmann A, Schmoranzer H, Schartner K-H (1993) Double-autoionization decay of resonantly excited single-electron states. J Phys B At Mol Opt Phys 26:1281–1300Google Scholar

Copyright information

© Springer-Verlag Berlin Heidelberg 2012

Authors and Affiliations

  1. 1.Racah Institute of PhysicsThe Hebrew UniversityJerusalemIsrael
  2. 2.Ioffe Physica-Technical InstituteSt. PetersburgRussia
  3. 3.Kurnakov Institute of General and Inorganic ChemistryMoscowRussia

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