###############################<16.54.qr.info.txt>##############################
#
#        X   X                X   X  X   X  X   X   III   X   X
#        X   X                X   X  X   X  X   X    I    X   X
#         X X    eee           X X    X X    X X     I     X X
#          X    e   e           X      X      X      I      X
#         X X   eeeee          X X    X X    X X     I     X X
#        X   X  e             X   X  X   X  X   X    I    X   X
#        X   X  e   e         X   X  X   X  X   X    I    X   X
#        X   X   eee          X   X  X   X  X   X   III   X   X
#
#===============================================================================
#
#    Z = 54,  Ne = 16,  Ion = 38
#
#    Xe XXXIX  Xenon
#
#    2015-06-12
#
#    Author: P. Bogdanovich     <pavelas.bogdanovicius@tfai.vu.lt>
#
#===============================================================================
#
#    Approach used: QR+CI.
#    Energy operator: Breit-Pauli.
#    References: [05-3,08-3].
#
#===============================================================================
#
#    INVESTIGATED CONFIGURATIONS:
#    ground + excited = EVEN ( 4)
#  2p6 3s2 3p4
#  2p6 3p6
#  2p6 3s1 3p4 3d1
#  2p6 3s2 3p2 3d2
#    excited        = ODD  ( 4)
#  2p6 3s1 3p5
#  2p6 3s2 3p3 3d1
#  2p6 3p5 3d1
#  2p6 3s1 3p3 3d2
#
#    The number of the investigated levels:
#    EVEN -    173     ODD  -    336
#
#    Closed inner shells [Be] not listed.
#    All listed shells were active in the CI approach.
#
#===============================================================================
#
#    INFORMATION ABOUT MULTICONFIGURATION APPROACH USED
#
#    RADIAL ORBITAL BASE:
#    The number of radial orbitals = 42
#    QR - quasirelativistic radial orbital [05-4,06-5,07-3]
#    TRO - transformed radial orbital
#          for virtual excitations [99-4,08-3]
#    1s QR     2s QR     2p QR     3s QR     3p QR
#    3d QR     4s TRO    4p TRO    4d TRO    4f TRO
#    5s TRO    5p TRO    5d TRO    5f TRO    5g TRO
#    6s TRO    6p TRO    6d TRO    6f TRO    6g TRO
#    6h TRO    7s TRO    7p TRO    7d TRO    7f TRO
#    7g TRO    7h TRO    7i TRO    8p TRO    8d TRO
#    8f TRO    8g TRO    8h TRO    8i TRO    8k TRO
#    9d TRO    9f TRO    9g TRO    9h TRO    9i TRO
#    9k TRO    9l TRO
#
#===============================================================================
#
#    ADMIXED CONFIGURATION SELECTION REZULTS
#
#    Common passive shells:   1s  2s
#
#    One-electron virtual excitations {nl->n`l`} were included.               
#    They include Brillouin`s {nl->n`l} excitations.                          
#    Paired virtual excitations {nl(2)->n`l`(2)} were included.               
#    Non-paired virtual excitations {nl(2)->n`l` n``l``;  nl nl->n`l`(2);...} 
#    were included.                                                           
#    Admixed configurations were selected by their averaged weights Wi.
#
#
#    Averaged energy corrections Ei and weights Vi of admixed configurations
#    were calculated in the second order of perturbation theory [01-2].
#
#    Averaged weights of admixed configurations were normalized:
#    Wi=Vi/(1+SUM(Vi)).
#
#-------------------------------------------------------------------------------
#    Description of Data
#-------------------------------------------------------------------------------
# Units   Label          Explanation
#-------------------------------------------------------------------------------
# ---     NT             Total possible number of admixed configurations
# a.u.    ET             Sum of Ei of all admixed configurations
# ---     WT             Sum of Wi of all admixed configurations
# ---     NS             Number of selected admixed configurations
# ---     w              Admixed configurations selection criterion value
# a.u.    ES             Sum of Ei of selected configurations
# ---     WS             Sum of Wi of selected configurations
#  %      E%             100%*ES/ET
#  %      W%             100%*WS/WT
# ---     Configuration  Adjusted configuration
#-------------------------------------------------------------------------------
#   NT    ET       WT      NS    w       ES       WS      E%   W%  Configuration
#-------------------------------------------------------------------------------
# 1283 1.04E+00 2.40E-03   42 1.0E-05 8.07E-01 2.36E-03  78%  98%  3s2 3p4
#  826 5.58E+02 1.00E+00   43 1.0E-05 5.58E+02 1.00E+00 100% 100%  3p6
# 2019 3.45E+00 9.58E-01   50 1.0E-05 3.20E+00 9.58E-01  93% 100%  3s1 3p4 3d1
# 2404 1.32E+00 2.23E-02   54 1.0E-05 1.08E+00 2.23E-02  82% 100%  3s2 3p2 3d2
# 1200 2.31E+00 1.05E-01   42 1.0E-05 2.08E+00 1.05E-01  90% 100%  3s1 3p5
# 2077 1.09E+00 9.75E-03   47 1.0E-05 8.38E-01 9.70E-03  77%  99%  3s2 3p3 3d1
# 1418 3.53E+00 1.84E-01   47 1.0E-05 3.29E+00 1.84E-01  93% 100%  3p5 3d1
# 2361 1.26E+00 2.34E-02   58 1.0E-05 1.03E+00 2.33E-02  81% 100%  3s1 3p3 3d2
#-------------------------------------------------------------------------------
#-------------------------------------------------------------------------------
#
#    The final numbers of selected
#    admixed configurations [01-2,01-4,05-1,06-2]
#    EVEN -   142     ODD  -   142
#
#    The total number of terms
#    (configuration state functions)
#    of all mixed configurations:
#    EVEN -   238658     ODD  -   452784
#
#    The used reduced [02-1,04-1] number of terms
#    (configuration state functions)
#    of all mixed configurations:
#    EVEN -    58914     ODD  -   121233
#
#    For byte-by-byte description of Energy Level Data see
#    <16.54.qr.elev.txt>
#
#===============================================================================
#
#    Explanation of the Radiative Transition Data
#
#    Electron transitions were calculated
#    for such types of transitions:
#    EVEN -> EVEN    M1  E2
#    ODD  -> EVEN    E1  M2  E3
#    ODD  -> ODD     M1  E2
#
#    Number of all calculated transitions   201617
#
#    File <16.54.qr.tran.txt> contains selected transitions
#    with emission probabilities A > Amax * 1.0E-02
#
#    Number of selected transitions          12072
#
#    Transitions from each initial level were ordered
#    in descending probabilities order.
#
#   For byte-by-byte description of Radiative Transition Data see
#   <16.54.qr.tran.txt>
#
#===============================================================================
#
#    Explanation of Electron-impact Excitation Data
#
#    Excitations by electron impact
#    (plane-wave Born approximation)
#    were calculated for  508 lowest levels.
#
#    Total number excitations   113024: 61889 even; 51135 odd.
#
#    Order  Number of excitations
#      0     2719  EVEN - EVEN
#      2    10596  EVEN - EVEN
#      4    10147  EVEN - EVEN
#      1    29259  EVEN - ODD
#      3    44900  EVEN - ODD
#      0    10003  ODD  - ODD
#      2    40011  ODD  - ODD
#      4    41128  ODD  - ODD
#
#    Ionization energy according NIST database is    2726.000 eV.
#
#    Excitation calculated for   10 electron energies
#    Impacting electron energies were specified by the excitation energies
#    Eel(eV) = Ki * Eex(eV)
#    Values of Ki coefficients:
#    1.100E+00 1.200E+00 1.550E+00 2.000E+00 3.000E+00
#    5.500E+00 1.000E+01 2.000E+01 5.500E+01 1.000E+02
#
#    For byte-by-byte description of Electron-impact Excitation Data see
#    <16.54.qr.exxs.txt> - Cross Section Table
#    <16.54.qr.excs.txt> - Collision Strengths Table
#    <16.54.qr.ecst.txt> - Effective Collision Strengths Table
#
#===============================================================================
#
#    COMMENTS:
#
###############################<16.54.qr.info.txt>##############################