c ******************* 786 **************************** c Ref: "Electron-Ion Recombination Rate Coefficients and Photoionization Cross Sections for Astrophysically Abundant Elements. XII. Na IX, Na X, Mg X, and Mg XI for UV and X-ray modeling", Sultana N. Nahar, Astrophys. J. Suppl. 167, 315 (2006) c **************************************************** c Mg XII : Energies, Oscillator strengths and decay rates for allowed (E1) and forbidden (E2,E3,M1,m2) transitions (1s to 4f) Process: Mg XII + h\nu <-> Mg XII* Contents of the file (contains both LS and fine structure transitions): --------------------- i) Table 1 - Ion Information and Configuration Set: ii) LS Term Energies (Relative to the ground) iii) Transitions in pure LS coupling - Oscillator Strengths: iv) Fine Structure energies: relativistic(BP): v-a) Same Spin-Multiplicity Dipole allowed E1 (E1d) fine structure transitions v-b) Fine structure intercombination (E1i) transitions vi) Forbidden Electric Octupole E3 & Magnetic Quadrupole M2 transitions: vii) Forbidden Electric Quadrupole E2 & Magnetic Dipole M1 transitions: --------------------------------------------------------------------------- i) Table 1 - Ion Information and Configuration Set: --------------------------------------------------- Ion: nz = 12, nelc = 1 Total Number of LS terms= 10 Configuration set: 10 configurations: first 10 spectroscopic, rest 0 correlation 1 1s 2 2s 3 2p 4 3s 5 3p 6 3d 7 4s 8 4p 9 4d 10 4f Number of orbitals = 10 Scaling parameters of the orbitals: 1.00000(1s) 1.00000(2s) 1.00000(2p) 1.00000(3s) 0.00000(3p) 1.00000(3d) 1.00000(4s) 1.00000(4p) 1.00000(4d) 1.00000(4f) -------------------------------------------------------------------------- ii) LS Term Energies (Relative to the ground) ---------------------------------------------- i SLP E(Rel,Ry) cfg# 1 2Se 0.000000 1 2 2Po 108.000063 3 3 2Se 108.000085 2 4 2De 128.000059 6 5 2Po 128.000063 5 6 2Se 128.000065 4 7 2Fo 135.000059 10 8 2De 135.000059 9 9 2Se 135.000087 7 10 2Po 135.000642 8 Number of first LS terms optimized = 10 -------------------------------------------------------------------------- iii) Transitions in pure LS coupling - Oscillator Strengths: ------------------------------------------------------------ Table Explanation: ------------------ LSi:CFi -> Initial LS term & configuration number as in Table 1 LSf:CFf -> Final LS term & configuration number as in Table 1 fL, fV -> oscillator strengths in length and velocity forms -------------------- Ni LSi:CFi Nf LSf:CFf Ei Ef aji(s-1) fL fV %diff 1 2Se: 1 2 2Po: 3 0.0000 108.0001 1.300E+13 4.16E-01 4.16E-01 0.0E+00 1 2Se: 1 5 2Po: 5 0.0000 128.0001 3.470E+12 7.91E-02 7.91E-02 0.0E+00 1 2Se: 1 10 2Po: 8 0.0000 135.0006 1.415E+12 2.90E-02 2.90E-02 0.0E+00 2 2Po: 3 4 2De: 6 108.0001 128.0001 1.341E+12 6.96E-01 6.96E-01 4.8E-04 2 2Po: 3 6 2Se: 4 108.0001 128.0001 1.310E+11 1.36E-02 1.36E-02 2.5E-02 2 2Po: 3 8 2De: 9 108.0001 135.0001 4.279E+11 1.22E-01 1.22E-01 0.0E+00 2 2Po: 3 9 2Se: 7 108.0001 135.0001 5.349E+10 3.04E-03 3.05E-03 1.6E-01 3 2Se: 2 5 2Po: 5 108.0001 128.0001 4.657E+11 4.35E-01 4.35E-01 2.3E-03 3 2Se: 2 10 2Po: 8 108.0001 135.0006 2.007E+11 1.03E-01 1.03E-01 0.0E+00 4 2De: 6 7 2Fo:10 128.0001 135.0001 2.861E+11 1.02E+00 1.02E+00 0.0E+00 4 2De: 6 10 2Po: 8 128.0001 135.0006 7.214E+09 1.10E-02 1.10E-02 4.5E-02 5 2Po: 5 8 2De: 9 128.0001 135.0001 1.460E+11 6.18E-01 6.18E-01 2.7E-04 5 2Po: 5 9 2Se: 7 128.0001 135.0001 3.808E+10 3.23E-02 3.23E-02 0.0E+00 6 2Se: 4 10 2Po: 8 128.0001 135.0006 6.362E+10 4.85E-01 4.85E-01 3.1E-03 8 2De: 9 10 2Po: 8 135.0001 135.0006 1.061E+00 2.30E-04 2.00E-05 8.4E+01 9 2Se: 7 10 2Po: 8 135.0001 135.0006 5.721E-01 6.90E-04 6.50E-04 3.0E+00 LS transitions: Number of oscillator strengths = 16 ----------------------------------------------------------------------------- iv) Fine Structure energies: relativistic(BP): ----------------------------------------------- Theory Expt(+Theo with 0% diff) ie SLp(cf#) 2J k*cm E(Ry) cfg SLP E(Ry) %df 1 2Se( 1) 2 0.0 0.00000E+00 2 2Po( 3) 2 11872482.0 1.08190E+02 3 2Se( 2) 2 11872508.0 1.08190E+02 4 2Po( 3) 4 11880071.0 1.08259E+02 5 2Po( 5) 2 14073352.0 1.28246E+02 6 2Se( 4) 2 14073361.0 1.28246E+02 7 2De( 6) 4 14075588.0 1.28266E+02 8 2Po( 5) 4 14075590.0 1.28266E+02 9 2De( 6) 6 14076337.0 1.28273E+02 10 2Se( 7) 2 14843351.0 1.35263E+02 11 2Po( 8) 2 14843408.0 1.35263E+02 12 2De( 9) 4 14844281.0 1.35271E+02 13 2Po( 8) 4 14844346.0 1.35272E+02 14 2Fo(10) 6 14844596.0 1.35274E+02 15 2De( 9) 6 14844596.0 1.35274E+02 16 2Fo(10) 8 14844754.0 1.35275E+02 ------------------------------------------------------------------------ v-a) Same Spin-Multiplicity Dipole allowed E1 (E1d) fine structure transitions -------------------------------------------------------- Table Explanation: ----------------- SLpCi -> initial symmetry (2S+1)Lpi(parity) & configuration number as in Table 1 SLpCi -> final symmetry (2S+1)Lpi(parity) & configuration number as in Table 1 fij, S, aji -> Oscillator strength fij, line strengh S & transition probability aji for electic dipole E1 same-spin transition ------------------------ Ni Nj SLpCi SLpCj gi gj wl(A) Ei(Ry) Ej(Ry) fij S aji(s-1) 1 2 2Se 1 2Po 3 2 2 8.42 0.00 108.19 1.38E-01 7.645E-03 1.30E+13 1 4 2Se 1 2Po 3 2 4 8.42 0.00 108.26 2.75E-01 1.526E-02 1.30E+13 3 4 2Se 2 2Po 3 2 4 13223 108.19 108.26 2.87E-03 2.497E-01 5.47E+04 1 5 2Se 1 2Po 5 2 2 7.11 0.00 128.25 2.58E-02 1.208E-03 3.41E+12 3 5 2Se 2 2Po 5 2 2 45.44 108.19 128.25 1.44E-01 4.311E-02 4.66E+11 2 6 2Po 3 2Se 4 2 2 45.44 108.19 128.25 1.33E-02 3.979E-03 4.30E+10 4 6 2Po 3 2Se 4 4 2 45.59 108.26 128.25 1.38E-02 8.268E-03 8.84E+10 2 7 2Po 3 2De 6 2 4 45.39 108.19 128.27 6.92E-01 2.068E-01 1.12E+12 4 7 2Po 3 2De 6 4 4 45.55 108.26 128.27 6.95E-02 4.166E-02 2.23E+11 5 7 2Po 5 2De 6 2 4 44721 128.25 128.27 3.18E-03 9.376E-01 5.31E+03 1 8 2Se 1 2Po 5 2 4 7.10 0.00 128.27 5.20E-02 2.432E-03 3.44E+12 3 8 2Se 2 2Po 5 2 4 45.39 108.19 128.27 2.86E-01 8.556E-02 4.63E+11 6 8 2Se 4 2Po 5 2 4 44864 128.25 128.27 5.07E-03 1.499E+00 8.41E+03 4 9 2Po 3 2De 6 4 6 45.53 108.26 128.27 6.25E-01 3.749E-01 1.34E+12 8 9 2Po 5 2De 6 4 6 133825 128.27 128.27 9.57E-04 1.687E+00 2.38E+02 2 10 2Po 3 2Se 7 2 2 33.66 108.19 135.26 2.77E-03 6.129E-04 1.63E+10 4 10 2Po 3 2Se 7 4 2 33.75 108.26 135.26 2.99E-03 1.330E-03 3.50E+10 5 10 2Po 5 2Se 7 2 2 129.87 128.25 135.26 3.14E-02 2.686E-02 1.24E+10 8 10 2Po 5 2Se 7 4 2 130.25 128.27 135.26 3.25E-02 5.569E-02 2.55E+10 1 11 2Se 1 2Po 8 2 2 6.74 0.00 135.26 9.20E-03 4.081E-04 1.35E+12 3 11 2Se 2 2Po 8 2 2 33.66 108.19 135.26 3.34E-02 7.401E-03 1.97E+11 6 11 2Se 4 2Po 8 2 2 129.86 128.25 135.26 1.60E-01 1.367E-01 6.32E+10 7 11 2De 6 2Po 8 4 2 130.24 128.27 135.26 9.21E-03 1.579E-02 7.24E+09 2 12 2Po 3 2De 9 2 4 33.65 108.19 135.27 1.21E-01 2.673E-02 3.55E+11 4 12 2Po 3 2De 9 4 4 33.74 108.26 135.27 1.21E-02 5.371E-03 7.08E+10 5 12 2Po 5 2De 9 2 4 129.71 128.25 135.27 6.11E-01 5.223E-01 1.21E+11 8 12 2Po 5 2De 9 4 4 130.09 128.27 135.27 6.17E-02 1.056E-01 2.43E+10 11 12 2Po 8 2De 9 2 4 114497 135.26 135.27 5.32E-03 4.009E+00 1.35E+03 1 13 2Se 1 2Po 8 2 4 6.74 0.00 135.27 1.87E-02 8.275E-04 1.37E+12 3 13 2Se 2 2Po 8 2 4 33.65 108.19 135.27 6.70E-02 1.483E-02 1.97E+11 6 13 2Se 4 2Po 8 2 4 129.70 128.25 135.27 3.18E-01 2.712E-01 6.30E+10 7 13 2De 6 2Po 8 4 4 130.08 128.27 135.27 1.80E-03 3.088E-03 7.10E+08 9 13 2De 6 2Po 8 6 4 130.21 128.27 135.27 1.10E-02 2.828E-02 6.49E+09 10 13 2Se 7 2Po 8 2 4 100577 135.26 135.27 7.56E-03 5.008E+00 2.49E+03 7 14 2De 6 2Fo10 4 6 130.04 128.27 135.27 1.02E+00 1.739E+00 2.67E+11 9 14 2De 6 2Fo10 6 6 130.16 128.27 135.27 4.84E-02 1.244E-01 1.90E+10 12 14 2De 9 2Fo10 4 6 317663 135.27 135.27 1.01E-03 4.204E+00 4.43E+01 4 15 2Po 3 2De 9 4 6 33.73 108.26 135.27 1.09E-01 4.849E-02 4.27E+11 8 15 2Po 5 2De 9 4 6 130.04 128.27 135.27 5.54E-01 9.495E-01 1.46E+11 13 15 2Po 8 2De 9 4 6 398790 135.27 135.27 1.37E-03 7.207E+00 3.84E+01 9 16 2De 6 2Fo10 6 8 130.14 128.27 135.28 9.68E-01 2.489E+00 2.86E+11 15 16 2De 9 2Fo10 6 8 634478 135.27 135.28 4.78E-04 5.993E+00 5.95E+00 Number of non-zero E1 transitions = 42 Number of dipole transitions, E1d = 42 Number of lines in the table = 65 v-b) Fine structure intercombination (E1i) transitions ------------------------------------------------------ Fine structure E1i intercombination transitions in Breit-Pauli approx: Ni Nj SLpCi SLpCj gi gj wl(A) Ei(Ry) Ej(Ry) fij S aji(s-1) Number of non-zero E1 transitions = 42 Number of intercombination transitions, E1i = 0 Number of lines in the table = 65 ------------------------------------------------------------------------------ vi) Forbidden Electric Octupole E3 & Magnetic Quadrupole M2 transitions: ------------------------------------------------------ Table Explanation: ----------------- SLpCi -> initial symmetry (2S+1)Lpi(parity) & configuration number as in Table 1 SLpCi -> final symmetry (2S+1)Lpi(parity) & configuration number as in Table 1 SE3, AE3 -> line strengh S & transition probability A for electic octupole E3 transition SM2, AM2 -> line strengh S & transition probability A for magnetic quadrupole M2 transition ------------------------ Forbidden octu E3 and quadrupole M2 transitions in Breit-Pauli approximation: Ni Nj SLpCi SLpCj gi gj wl(A) Ei(Ry) Ej(Ry) SE3 AE3(s-1) SM2 AM2(s-1) 2 9 2Po 3 2De 6 2 6 45.38 1.082E+02 1.283E+02 3.22E-02 8.52E+03 5.29E+00 6.84E+04 5 9 2Po 5 2De 6 2 6 33505 1.282E+02 1.283E+02 9.92E-01 2.19E-15 2.40E+01 1.41E-09 9 11 2De 6 2Po 8 6 2 130.37 1.283E+02 1.353E+02 6.33E-01 3.11E+02 4.11E-01 8.14E+01 1 14 2Se 1 2Fo10 2 6 6.74 0.000E+00 1.353E+02 3.52E-08 5.85E+03 0.00E+00 0.00E+00 3 14 2Se 2 2Fo10 2 6 33.65 1.082E+02 1.353E+02 2.52E-02 5.41E+04 0.00E+00 0.00E+00 6 14 2Se 4 2Fo10 2 6 129.66 1.282E+02 1.353E+02 2.87E+00 4.88E+02 0.00E+00 0.00E+00 10 14 2Se 7 2Fo10 2 6 80330 1.353E+02 1.353E+02 1.42E+01 6.90E-17 0.00E+00 0.00E+00 2 15 2Po 3 2De 9 2 6 33.65 1.082E+02 1.353E+02 1.70E-05 3.66E+01 6.86E-01 3.96E+04 5 15 2Po 5 2De 9 2 6 129.66 1.282E+02 1.353E+02 2.76E+00 4.70E+02 1.34E+01 9.05E+02 11 15 2Po 8 2De 9 2 6 84150 1.353E+02 1.353E+02 4.73E+01 1.66E-16 1.03E+02 6.04E-11 1 16 2Se 1 2Fo10 2 8 6.74 0.000E+00 1.353E+02 4.69E-08 5.85E+03 0.00E+00 0.00E+00 3 16 2Se 2 2Fo10 2 8 33.64 1.082E+02 1.353E+02 3.36E-02 5.41E+04 0.00E+00 0.00E+00 6 16 2Se 4 2Fo10 2 8 129.64 1.282E+02 1.353E+02 3.83E+00 4.89E+02 0.00E+00 0.00E+00 7 16 2De 6 2Fo10 4 8 130.01 1.283E+02 1.353E+02 1.04E+00 1.31E+02 4.24E+01 2.13E+03 10 16 2Se 7 2Fo10 2 8 71294 1.353E+02 1.353E+02 1.89E+01 1.59E-16 0.00E+00 0.00E+00 12 16 2De 9 2Fo10 4 8 211608 1.353E+02 1.353E+02 1.30E+01 5.39E-20 1.02E+02 4.50E-13 Number of transitions: E3 = 16, M2 = 8, Total E3+M2 = 24 Total number of lines of M2/E3 transitions = 16 ---------------------------------------------------------------------------- vii) Forbidden Electric Quadrupole E2 & Magnetic Dipole M1 transitions: ----------------------------------------------------- Table Explanation: ----------------- SLpCi -> initial symmetry (2S+1)Lpi(parity) & configuration number as in Table 1 SLpCi -> final symmetry (2S+1)Lpi(parity) & configuration number as in Table 1 SE2, AE2 -> line strengh S & transition probability A for electric quadrupole E2 transition SM1, AM1 -> line strengh S & transition probability A for magnetic dipole M1 transition ------------------------ Forbidden quad E2 and dipoe M1 transitions in Breit-Pauli approximation: Ni Nj SLpCi SLpCj gi gj wl(A) Ei(Ry) Ej(Ry) SE2 AE2(s-1) SM1 AM1(s-1) 1 3 2Se 1 2Se 2 2 2 8.42 0.000E+00 1.082E+02 0.00E+00 0.00E+00 6.93E-06 1.56E+05 2 4 2Po 3 2Po 3 2 4 13176 1.082E+02 1.083E+02 2.30E-02 2.43E-05 1.33E+00 3.92E+00 2 5 2Po 3 2Po 5 2 2 45.44 1.082E+02 1.282E+02 0.00E+00 0.00E+00 2.12E-07 3.04E+01 4 5 2Po 3 2Po 5 4 2 45.59 1.083E+02 1.282E+02 1.67E-02 7.13E+07 6.13E-06 8.72E+02 1 6 2Se 1 2Se 4 2 2 7.11 0.000E+00 1.282E+02 0.00E+00 0.00E+00 1.90E-06 7.14E+04 3 6 2Se 2 2Se 4 2 2 45.44 1.082E+02 1.282E+02 0.00E+00 0.00E+00 8.09E-07 1.16E+02 1 7 2Se 1 2De 6 2 4 7.10 0.000E+00 1.283E+02 7.78E-05 1.80E+09 6.24E-08 1.17E+03 3 7 2Se 2 2De 6 2 4 45.39 1.082E+02 1.283E+02 7.05E-02 1.54E+08 1.76E-07 1.27E+01 6 7 2Se 4 2De 6 2 4 44890 1.282E+02 1.283E+02 5.20E-01 1.20E-06 6.20E-09 4.62E-10 2 8 2Po 3 2Po 5 2 4 45.39 1.082E+02 1.283E+02 1.63E-02 3.56E+07 2.54E-06 1.83E+02 4 8 2Po 3 2Po 5 4 4 45.55 1.083E+02 1.283E+02 1.66E-02 3.56E+07 3.07E-06 2.19E+02 5 8 2Po 5 2Po 5 2 4 44695 1.282E+02 1.283E+02 8.30E-01 1.95E-06 1.33E+00 1.01E-01 1 9 2Se 1 2De 6 2 6 7.10 0.000E+00 1.283E+02 1.17E-04 1.80E+09 0.00E+00 0.00E+00 3 9 2Se 2 2De 6 2 6 45.38 1.082E+02 1.283E+02 1.06E-01 1.54E+08 0.00E+00 0.00E+00 6 9 2Se 4 2De 6 2 6 33600 1.282E+02 1.283E+02 7.80E-01 5.10E-06 0.00E+00 0.00E+00 7 9 2De 6 2De 6 4 6 133593 1.283E+02 1.283E+02 1.75E-01 1.15E-09 2.40E+00 4.52E-03 1 10 2Se 1 2Se 7 2 2 6.74 0.000E+00 1.353E+02 0.00E+00 0.00E+00 9.77E-07 4.31E+04 3 10 2Se 2 2Se 7 2 2 33.66 1.082E+02 1.353E+02 0.00E+00 0.00E+00 2.92E-07 1.03E+02 6 10 2Se 4 2Se 7 2 2 129.87 1.282E+02 1.353E+02 0.00E+00 0.00E+00 2.03E-07 1.25E+00 7 10 2De 6 2Se 7 4 2 130.25 1.283E+02 1.353E+02 5.43E-02 1.22E+06 2.54E-11 1.55E-04 9 10 2De 6 2Se 7 6 2 130.38 1.283E+02 1.353E+02 8.25E-02 1.84E+06 0.00E+00 0.00E+00 2 11 2Po 3 2Po 8 2 2 33.66 1.082E+02 1.353E+02 0.00E+00 0.00E+00 6.57E-08 2.32E+01 4 11 2Po 3 2Po 8 4 2 33.75 1.083E+02 1.353E+02 1.54E-03 2.95E+07 1.47E-06 5.18E+02 5 11 2Po 5 2Po 8 2 2 129.86 1.282E+02 1.353E+02 0.00E+00 0.00E+00 6.39E-08 3.93E-01 8 11 2Po 5 2Po 8 4 2 130.24 1.283E+02 1.353E+02 3.38E-01 7.58E+06 5.57E-06 3.40E+01 1 12 2Se 1 2De 9 2 4 6.74 0.000E+00 1.353E+02 3.79E-05 1.15E+09 2.80E-08 6.17E+02 3 12 2Se 2 2De 9 2 4 33.65 1.082E+02 1.353E+02 1.52E-03 1.48E+07 4.71E-08 8.33E+00 6 12 2Se 4 2De 9 2 4 129.72 1.282E+02 1.353E+02 9.86E-01 1.13E+07 1.73E-08 5.34E-02 7 12 2De 6 2De 9 4 4 130.09 1.283E+02 1.353E+02 2.20E-01 2.48E+06 3.69E-07 1.13E+00 9 12 2De 6 2De 9 6 4 130.22 1.283E+02 1.353E+02 9.48E-02 1.06E+06 1.20E-06 3.67E+00 10 12 2Se 7 2De 9 2 4 107520 1.353E+02 1.353E+02 7.43E+00 2.17E-07 3.94E-09 2.13E-11 2 13 2Po 3 2Po 8 2 4 33.65 1.082E+02 1.353E+02 1.43E-03 1.39E+07 4.97E-07 8.79E+01 4 13 2Po 3 2Po 8 4 4 33.74 1.083E+02 1.353E+02 1.54E-03 1.48E+07 9.88E-07 1.74E+02 5 13 2Po 5 2Po 8 2 4 129.70 1.282E+02 1.353E+02 3.30E-01 3.77E+06 3.65E-06 1.13E+01 8 13 2Po 5 2Po 8 4 4 130.08 1.283E+02 1.353E+02 3.36E-01 3.79E+06 9.32E-07 2.85E+00 11 13 2Po 8 2Po 8 2 4 106656 1.353E+02 1.353E+02 9.27E+00 2.82E-07 1.33E+00 7.41E-03 2 14 2Po 3 2Fo10 2 6 33.65 1.082E+02 1.353E+02 2.23E-02 1.45E+08 0.00E+00 0.00E+00 4 14 2Po 3 2Fo10 4 6 33.73 1.083E+02 1.353E+02 6.40E-03 4.11E+07 4.84E-08 5.67E+00 5 14 2Po 5 2Fo10 2 6 129.66 1.282E+02 1.353E+02 1.78E+00 1.36E+07 0.00E+00 0.00E+00 8 14 2Po 5 2Fo10 4 6 130.04 1.283E+02 1.353E+02 5.11E-01 3.85E+06 7.30E-08 1.49E-01 11 14 2Po 8 2Fo10 2 6 84162 1.353E+02 1.353E+02 5.20E+00 3.45E-07 0.00E+00 0.00E+00 13 14 2Po 8 2Fo10 4 6 399049 1.353E+02 1.353E+02 1.48E+00 4.10E-11 1.66E-09 1.18E-13 1 15 2Se 1 2De 9 2 6 6.74 0.000E+00 1.353E+02 5.70E-05 1.15E+09 0.00E+00 0.00E+00 3 15 2Se 2 2De 9 2 6 33.65 1.082E+02 1.353E+02 2.29E-03 1.49E+07 0.00E+00 0.00E+00 6 15 2Se 4 2De 9 2 6 129.66 1.282E+02 1.353E+02 1.48E+00 1.13E+07 0.00E+00 0.00E+00 7 15 2De 6 2De 9 4 6 130.04 1.283E+02 1.353E+02 9.40E-02 7.08E+05 3.73E-07 7.62E-01 9 15 2De 6 2De 9 6 6 130.16 1.283E+02 1.353E+02 3.78E-01 2.84E+06 1.84E-06 3.76E+00 10 15 2Se 7 2De 9 2 6 80320 1.353E+02 1.353E+02 1.11E+01 9.33E-07 0.00E+00 0.00E+00 12 15 2De 9 2De 9 4 6 317498 1.353E+02 1.353E+02 2.80E+00 2.43E-10 2.40E+00 3.37E-04 4 16 2Po 3 2Fo10 4 8 33.73 1.083E+02 1.353E+02 3.84E-02 1.85E+08 0.00E+00 0.00E+00 8 16 2Po 5 2Fo10 4 8 130.01 1.283E+02 1.353E+02 3.07E+00 1.73E+07 0.00E+00 0.00E+00 13 16 2Po 8 2Fo10 4 8 244877 1.353E+02 1.353E+02 8.89E+00 2.12E-09 0.00E+00 0.00E+00 14 16 2Fo10 2Fo10 6 8 633824 1.353E+02 1.353E+02 9.51E-01 1.96E-12 3.43E+00 4.54E-05 Number of transitions: E2 = 44, M1 = 39, Total E2+M1 = 83 Total number of transitions lines (including non-spectroscopic) = 53 NT= total number of forbidden (E2,M1,E3,M2) transitions = 83 + 24 = 107 Net allowed (E1) and forbidden (E2,M1,E3,M2) transitions = = 42 + 107 = 149