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Results of Calculations

Chapter
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Abstract

In this chapter, we provide figures and tables that represent data collected in the study of total and partial photoionization cross-sections, relative cross-sections, dipole and non-dipole parameters of angular anisotropy and spin polarization of photoelectrons, as well as the oscillator strengths of discrete excitations. In some cases, experimental data are presented.

Keywords

Total Photoionization Cross Section Discrete Excitation Angular Anisotropy Parameter RPA Correlations Spin Polarization Parameters 
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.

References

  1. 2.1.
    Amusia MYa, Ivanov VK, Dolmatov VK (1978) Giant autoionization in Mn atom. JETP Lett 4:1305–1309 (in Russian)Google Scholar
  2. 2.2.
    Amusia MYa, Dolmatov VK, Ivanov VK, Sheftel SI (1981) Giant autoionization of the atoms with semi-occupied shells. in: autoionization phenomena in atoms. In: Proceedings of the 2nd scientific workshop, Moscow State University, pp 235–242 (in Russian)Google Scholar
  3. 2.3.
    Amusia MYa, Chernysheva LV, Manson ST, Msezane AZ, Radojevich V (2002) Strong electron correlations in photoionization of spin–orbit doublets. Phys Rev Lett 88:093002Google Scholar
  4. 2.4.
    Bizau JM, Wuilleumier FJ (1995) Redetermination of absolute partial photoionization cross-sections of He and Ne atoms between 20 and 300 eV photon energy. J Electron Spectrosc Relat Phenom 71:205–224Google Scholar
  5. 2.5.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Msezane AZ, Nordgren J (2001) Directed motion of electrons in gases under the action of photon flux. Phys Rev A 63:052512Google Scholar
  6. 2.6.
    Amusia MYa, Cherepkov NA, Shapiro SG (1972) Calculation of multipole polarizabilities and van-der-waals force constants. JETP 63:889 (in Russian)Google Scholar
  7. 2.7.
    Amusia MYa, Baltenkov AS, Greenberg AA, Shapiro SG (1975) Investigation of the current due to photon momentum in monoatomic gases. JETP 68:28–35Google Scholar
  8. 2.8.
    Dias E, Chakraborty H, Deshmukh P, Manson ST, Hemmers O, Glans P, Hansen D, Wang H, Whitfield S, Lindle D, Wehlits R, Levin J, Sellin I, Perera R (1997) Breakdown of the independent particle approximation in high-energy photoionization. Phys Rev Lett 78:4553–4556Google Scholar
  9. 2.9.
    Amusia MYa, Avdonina NB, Drukarev EG, Manson ST., Pratt RH (2000) Modification of the high energy behavior of the atomic photoionization cross section. Phys Rev Lett 85(22):4703–4706Google Scholar
  10. 2.10.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Msezane AZ (2001) Non-dipole parameters in angular distributions of electrons in photoionization of noble gas atoms. Phys Rev A 63:052506Google Scholar
  11. 2.11.
    Amusia MYa, Cherepkov NA, Chernysheva LV (1971) Noble-gas photoionization cross section with many-electron correlations. JETP 60:160–174 (in Russian)Google Scholar
  12. 2.12.
    West JB, Marr GV (1976) The absolute photoionization cross sections of helium, neon, argon and krypton in the extreme vacuum ultraviolet region of the spectrum. Proc Roy Soc. London A 349(1658):397–421Google Scholar
  13. 2.13.
    Tan KH, Brion CE (1978) Branching ratios and the partial photoionization cross-section for the 3s electron of argon. J. Electron Spectrosc Relat Phenom 13:77–82Google Scholar
  14. 2.14.
    Amusia MYa (1981) Collective effects in an isolated atom. Bull Russ Acad Sci Phys 45(12):2242–2254 (in Russian)Google Scholar
  15. 2.15.
    Amusia MYa (1984) Interaction of complex atoms with radiation. Bull Russ Acad Sci Phys 48(4):642–650Google Scholar
  16. 2.16.
    Shnopper HW (1963) Multiple excitation and ionization of inner atomic shells by X rays. Phys Rev 131:2558–2560Google Scholar
  17. 2.17.
    Houlgate RG, West JB, Codling K, Marr GV (1974) Angular distribution and photoionization cross section measurements on the 3p and 3s subshells of argon. J Phys B 7:L470–L473Google Scholar
  18. 2.18.
    Dehmer JL, Chupka WA, Berkowitz J, Jivery WT (1975) Wavelength dependence of the photoelectron angular distributions of the rare gases. Phys Rev A 12:1966–1977Google Scholar
  19. 2.19.
    West JB, Woodruff PR, Codling K, Houlgate RG (1976) The 4d, 5s and 5p partial photoionization cross sections of xenon above the 4d threshold. J Phys B At Mol Phys 9:407–410Google Scholar
  20. 2.20.
    Amusia MYa, Ivanov VK, Cherepkov NA, Chernysheva LV (1974) Intershell and intersubshell effects in atomic photoionization JETP 66:1537–1549Google Scholar
  21. 2.21.
    Samson JAR, Gardner JL (1974) Photoionization cross sections of the outer s-subshell electrons in the rare gases. Phys Rev Lett 33:671–674Google Scholar
  22. 2.22.
    Adam MY, Wuilleumier F, Sandner N, Krummacher S, Schmidt V, Mehlhorn W (1978) Jpn J Appl Phys 17:170–180Google Scholar
  23. 2.23.
    Haensel R, Keitel G, Kosuch N, Nielsen U, Schreiber P (1971) Optical absorption of solid neon and argon in the soft X-ray region. J De Physique:236–245 (32-C4)Google Scholar
  24. 2.24.
    Kammerling B, Kossman H, Schmidt V (1989) 4d photoionization in xenon: absolute partial cross section and relative strength of 4d many-electron processes. J Phys B At Mol Phys 22:841–854Google Scholar
  25. 2.25.
    Amusia MYa (2004) Random phase approximation: from Giant to intra-doublet resonances. Radiat Phys Chem 70:237–251Google Scholar
  26. 2.26.
    Kivimaki A, Hergenhahn U, Kempgens B, Hentges R, Piancastelli MN, Maier K, Ruedel A, Tulkki JJ, Bradshaw AM (2000) Near-threshold study of Xe 3d photoionization. Phys Rev A 63:012716Google Scholar
  27. 2.27.
    Amusia MYa, Ivanov VK (1976) The peculiarities of photoelectron angular distribution and ionization cross section of 5p subshell in Xe. Phys Lett A 59:194–196Google Scholar
  28. 2.28.
    Lynch MJ, Gardner JL, Codling K, Marr GV (1973) The photoionization of the 3s subshell of argon in the threshold region by photoelectron spectroscopy. Phys Lett A 43:237–238Google Scholar
  29. 2.29.
    Torop L, Morton J, West JB (1976) The angular distribution of photoelectrons from xenon. J Phys B At Mol Phys 9:2035–2041Google Scholar
  30. 2.30.
    Krause MO, Carlson TA, Woodruff PR (1981) Angular distribution of photoelectrons of Xe 5p spin–orbit components between 20 and 105 eV. Phys Rev A 24:1374–1385Google Scholar
  31. 2.31.
    Southworth S, Becker U, Truesdale CM, Kobrin PH, Lindle DW, Owaki S, Shirley DA (1983) Electron-spectroscopy study of inner-shell photoexcitation and ionization of Xe. Phys Rev A 28:261–273Google Scholar
  32. 2.32.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Manson ST, Msezane AZ (2003) On the effect of intra-doublet correlations upon the non-dipole parameters in Xe. INFN Frasc Phys Ser 32:3–8Google Scholar
  33. 2.33.
    Hemmers O, Guillemin R, Kanter EP, Krassig B, Lindle D, Southworth S H, Wehlitz R, Baker J, Hudson A, Lotrakul M, Rolles D, Stolte WC, Tran IC, Wolska A, Yu SW, Amusia MYa, Cheng KT, Chernysheva LV, Johnson WR, Manson ST (2003) Dramatic nondipole effects in low energy photoionization: experimental and theoretical study of Xe5s. Phys Rev Lett 91:053002Google Scholar
  34. 2.34.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Manson ST, Msezane AZ (2003) Correlation structure in nondipole photoionization. Phys Rev A 67:060702Google Scholar
  35. 2.35.
    Amusia MYa, Ivanov VK, Chernysheva LV (1973) Photoproduction of Kr +  and Xe +  ions in the vicinity of the outer d-subshell threshold. Phys Lett A 43:243Google Scholar
  36. 2.36.
    Amusia MYa, Cherepkov NA, Chernysheva LV, Manson ST (2000) Multielectron effects in Xe\(^{++}\) formation resulting from the photoionization of Xe +  ions. J Phys B At Mol Opt Phys 33:L37–L42Google Scholar
  37. 2.37.
    Koizumi T, Awaya Y, Fujino A, Itoh T, Kitajima M, Kojima TM, Oura M. Sano, Sekioka T, Watanabe N, Koike F (1997) Phys Scripta T73:131–142Google Scholar
  38. 2.38.
    Ivanov VK, Lapkin KV, Kulov MA (2003) Electron photodetachment from the 1s shell of a negative lithium ion. Techn Phys Lett 29(8):620–623Google Scholar
  39. 2.39.
    Berrah N, Bozek JD, Wills AA, Turri G, Zhou HL, Manson ST, Akerman G, Rude B, Gibson ND, Walter CW, VoKy L, Hibbert A, Ferguson SM (2001) K-shell photodetachment of Li − : experiment and theory. Phys Rev Lett 87(25):253002-1/4Google Scholar
  40. 2.40.
    Kjeldsen H, Andersen P, Folkmann F, Kristensen B, Andersen T (2001) Inner-shell photodetachment of Li − . J Phys B At Mol Opt Phys 34(10):L353–L357Google Scholar
  41. 2.41.
    Kjeldsen H, Folkmann F, Knudsen H, Rasmussen MS, West JB, Andersen T (1999) Absolute photoionization cross section of K +  ions from the 3p to the 3s threshold. J Phys B At Mol Opt Phys 32(18):4457–4465Google Scholar
  42. 2.42.
    van Kampen P, O’Sullivan G, Ivanov VK, Ipatov AN, Costello JT, Kennedy ET (1997) Dramatic changes in the 3s autoionization process at the beginning of the Ar I sequence. Phys Rev Lett 78:3082–3085Google Scholar
  43. 2.43.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Manson ST, Msezane AZ (2004) Intra-doublet correlation effect in dipole angular anisotropy parameters of 3d electrons. J Phys B At Mol Opt Phys 37:937–944Google Scholar
  44. 2.44.
    Amusia MYa, Cherepkov NA, Chernysheva LV, Felfli Z, Msezane AZ (2004) On spin polarization of photoelectrons from Xe, Cs, and Ba 3d spin-orbit components. Phys Rev A 70:062709Google Scholar
  45. 2.45.
    Amusia MYa, Avdonina NB (1988) Intershell interaction in excited atom and ion photoionization. Z Phys D Atoms Mol Clust 14:191–194Google Scholar
  46. 2.46.
    Wilson NJ, Donnelly D, Bell KL, Hibbert A (1999) R-matrix calculation of the photoabsorption of K II, Ca III and Sc IV. J Phys B At Mol Opt Phys 32(18):4495–4508Google Scholar
  47. 2.47.
    Rabe A, Radler K, Wolf HW. (1974) Photoabsorption of metallic and atomic barium between 80 eV and 160 eV. Vacuum ultraviolet radiation physics. Pergamon & Vieweg, Braunschweig, West Germany, pp. 247–249Google Scholar
  48. 2.48.
    Amusia MYa, Chernysheva LV, Ivanov VK, Kupchenko VA (1989) Photoionization of lanthanum and its ions in the region of the giant resonance. Z Phys D Atoms Mol Clust 14(3):215–217Google Scholar
  49. 2.49.
    Amusia MYa, Ivanov VK, Kupchenko VA (1989) The photoionization of atomic Eu in the vicinity of its giant resonance. Z Phys D Atoms Mol Clust 14(3):219–221Google Scholar
  50. 2.50.
    Amusia MYa, Chernysheva LV, Ivanov VK (2000) On the photoabsorption of atomic Eu, Eu +  and Eu\(^{++}\) in the vicinity of 4d threshold radiation. Phys Chem 59:137–143Google Scholar
  51. 2.51.
    Becker U, Kerkhoff HG, Lindle DW, Kobrin PH, Ferret TA, Truesdale CM, Shirley DA (1986) Orbital-collapse effects in photoemission from atomic Eu. Phys Rev A 34:2858–2864Google Scholar
  52. 2.52.
    Richter M, Meyer M, Pahler M, Raven EV, Sonntag B (1989) Experimental study of atomic 4d giant resonances by photoabsorption and photoelectron spectroscopy: Sm, Eu, and Gd Phys Rev A 40:7007–7019Google Scholar
  53. 2.53.
    Amusia MYa, Sheftel SI, Chernysheva LV (1981) Nature of the giant resonance in photoionization cross section of Eu atom. J Techn Phys 51(11):2411 (in Russian)Google Scholar
  54. 2.54.
    Kojima TM, Oura M, Itoh Y, Koizumi T, Sano M, Sekioka T, Watanabe N, Yamaoka H, Awaya Y (1998) Photoion yield spectroscopy in the 4d photoionization of Eu + . Phys B At Mol Opt Phys 31:1463–1468Google Scholar
  55. 2.55.
    Amusia MYa, Gribakin GF, Ivanov VK, Chernysheva LV (1990) Many-electron correlations in the negative ion photodetachment. J Phys B At Mol Opt Phys 23:385–391Google Scholar
  56. 2.56.
    Gribakin GF, Gribakina AA, Gultsev BV, Ivanov VK (1992) Correlational autodetachment of the low lying shape resonances in C − , Si −  and Ge −  photodetachment. J Phys B At Mol Opt Phys 25:1757–1772Google Scholar
  57. 2.57.
    Lapkin CV, Ivanov VK (2004). In: Seventh International Workshop on Nondestructive Testing and Computer Simulations in Science and Engineering (NDTCS-2003, 9–15 June 2003, St. Petersburg, Russia). Ed. A.I. Melker/54, pp 42–46Google Scholar
  58. 2.58.
    Gibson ND, Walter CW, Zatsarinny O, Gorczyca T W, Akerman GD, Bozek JD, Martins M, McLaughlin BM, Berrah N (2003) K-shell photodetachment from C − : Experiment and theory. Phys Rev A 67:030703(R)-1–030703(R)-4Google Scholar
  59. 2.59.
    Balling P, Kristensen P, Stapelfeldt H, Andersen T, Haugen HK (1993) Window resonance in photodetachment of the negative silicon ion: strong interaction of the 3p continuum with the 3s to 3p shape resonance. J Phys B At Mol Opt Phys 26:3531–3539Google Scholar
  60. 2.60.
    Amusia MYa, Dolmatov VK, Ivanov VK (1983) Photoionization of atoms with half-filled shells. JETP 85(1):115–123 (in Russian)Google Scholar
  61. 2.61.
    Amusia MYa, Dolmatov VK, Ivanov VK, Shapiro SG (1983) Angular distribution of 3p-photoelectrons in Cr and Mn. J Phys B At Mol Phys 16(24):L753–L756Google Scholar
  62. 2.62.
    Amusia MYa, Chernysheva LV (2007) On the angular distribution and spin polarization of the photoelectrons from semi-filled shell atoms. http://arxiv.org/abs/physics/0701040
  63. 2.63.
    Ivanov VK, Krukovskaya LP, Kashenock GY (1996) Near-threshold shape resonance in Cr −  outer shell photodetachment. J Phys B At Mol Opt Phys 29(9):L313–L320Google Scholar
  64. 2.64.
    Cherepkov NA, Chernysheva LV (1977) Photoionization cross section of Cl atom in RPAE. Bull Russ Acad Sci Phys 41(12):2518–2528 (in Russian)Google Scholar
  65. 2.65.
    Samson JAR, Shefer Y, Angel GC (1986) A critical test of many-body theory: the photoionization cross section of Cl as an example of an open-shell atom. Phys Rev Lett 56:2020–2024Google Scholar
  66. 2.66.
    Amusia MYa, Ivanov VK, Chernysheva LV (1981) Peculiarities of the photoionization cross section of the Mn atom. J Phys B At Mol Phys 14:L19–L23Google Scholar
  67. 2.67.
    Amusia MYa, Dolmatov VK, Mansurov MM (1990) A new feature of 3p to 3d transitions in Mn atom. J Phys B At Mol Opt Phys 23:L491–L494Google Scholar
  68. 2.68.
    Amusia MYa, Dolmatov VK, Ivanov VK (1986) Non-dipole part of angular distribution of photoelectrons and entrainment current in atomic vapor of Mn. J Techn Phys 56(1):8–15 (in Russian)Google Scholar
  69. 2.69.
    Bruhn R, Schmidt E, Schroder H, Sonntag B (1982) Phys Lett A 90:41–44Google Scholar
  70. 2.70.
    Kobrin PH, Becker U, Truesdale CM, Lindle DW, Kerkhoff HG, Shirley DA (1984) Photoelectron asymmetries and two-electron satellites near the 3p − 3d giant resonance region in atomic Mn. J Electron Spectrosc Relat Phenom 34:129–139Google Scholar
  71. 2.71.
    Dolmatov VK, Amusia MYa (1994) Resonant structure of the 3d-electrons angular distribution in a free Mn +  ion. J Phys B At Mol Opt Phys 27:L281–L285Google Scholar
  72. 2.72.
    Amusia MY, Cherepkov NA, Chernysheva LV, Manson ST (2000) On the photoionization of the iodine atom and its ions. Phys Rev A 61:R207–R211Google Scholar
  73. 2.73.
    Kjeldsen H, Andersen P, Folkmann F, Knudsen H, Kristensen B, West JB, Andersen T (2000) Absolute photoionization cross sections of I +  and I2 +  in the 4d ionization region. Phys Rev A 62:020702Google Scholar
  74. 2.74.
    Amusia MY, Gribakin GF, Ivanov VK, Chernysheva LV (1986) Photodetachment from outer subshells of negative iodine ion. Bull Russ Acad Sci Phys 50(7):1274–1278 (in Russian)Google Scholar
  75. 2.75.
    Kjeldsen H (2000) Measurements of absolute cross sections for photoionisation of ions. http://physics.nist.gov
  76. 2.76.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Msezane AZ (2005) Near-threshold behavior of angular anisotropy parameters in negative ions photo-detachment. Phys Rev A 72:032727Google Scholar
  77. 2.77.
    Amusia MYa, Baltenkov AS, Chernysheva LV (2008) Giant resonances of endohedral atoms. JETP Lett 87(4):230–233Google Scholar
  78. 2.78.
    Amusia MYa, Baltenkov AS, Chernysheva LV (2008) On the photoionization of the outer electrons in noble gas endohedral atoms. JETP 134(2):221–230Google Scholar
  79. 2.79.
    Amusia MYa, Baltenkov AS, Chernysheva LV (2008) Photoionization of subvalent electrons in noble gas endohedrals: interference of three resonances. J Phys B At Mol Opt Phys 41:165201Google Scholar
  80. 2.80.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Msezane AZ (2005) Dramatic distortion of 4d giant resonance by the fullerenes C60 shell. J Phys B At Mol Opt Phys 38:L169–L173Google Scholar
  81. 2.81.
    Amusia MYa, Baltenkov AS, Chernysheva LV, Felfli Z, Msezane AZ (2006) Modification of the Xe 4dgiant resonance by the C60 shell in molecular Xe@C60. JETP 129(1):63–70Google Scholar
  82. 2.82.
    Amusia MYa, Baltenkov AS, Chernysheva LV (2008) Photoionization of 3d electrons of Xe, Cs and Ba endohedral atoms: comparative analyses. Central Eur J Phys 6(1):14–25Google Scholar
  83. 2.83.
    Kilcoyne ALD, Aguilar A, Müller A, Schippers S, Cisneros C, Alna’Washi G, Aryal NB, Baral KK, Esteves DA, Thomas CM, and Phaneuf RA (2010) Confinement resonances in photoionization of Xe@C60  + . Phys Rev Lett 105: 213001(4)Google Scholar
  84. 2.84.
    Amusia MYa, Baltenkov AS, Chernysheva LV (2007) Photoionization of Xe 3d electrons in molecule Xe@C60: interplay of intra-doublet and confinement resonances. Phys Rev A 75:043201Google Scholar
  85. 2.85.
    Amusia MYa, Chernysheva LV, Ivanov VK, Kupchenko VA (1989) Photoionization of lanthanum and its ions in the region of the giant resonance. Z Phys D Atoms Mol Clust 14(3):215–217Google Scholar
  86. 2.86.
    Amusia MYa, Baltenkov AS, Chernysheva LV (2008) Distortion and preservation of giant resonances in endohedral atoms A@C60 JETP Lett 89(6):322–326Google Scholar
  87. 2.87.
    Amusia MYa, Liverz EZ, Chernysheva LV (2009) Photoionization of atoms stuffed inside a two-shell fullerene, (with L. V. Chernysheva and E. Z. Liverts). Phys Rev A 80:032503-1–032503-12Google Scholar
  88. 2.88.
    Amusia MYa, Liverz EZ, Chernysheva LV (2009) Photoionization of onion-type atoms (with L.V. Chernysheva, E.Z. Liverts). Pis’ma v ZhETF 90(5):393–397 (JETP Lett 90:350–354)Google Scholar
  89. 2.89.
    Houlgate RG, West JB, Codling K, Marr GV (1976) The angular distribution of the 3p electrons and the partial cross section of the 3s electrons of argon from threshold to 70 eV. J Electron Spectrosc Relat Phenom 9:205–209Google Scholar

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© 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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