Geant4 Cross Reference |
1 1 2 The photo-evaporation database contains nuclea 2 The photo-evaporation database contains nuclear deexcitation data starting 3 from a given nuclear level including informati << 3 from a given nuclear level. Each file contains data for a given isotope, 4 angular moment of a transition in a directory << 4 identified by Z and A. 5 5 6 correlated_gamma of this dataset << 6 The database must first be downloaded from 7 << 8 ********************************************** << 9 << 10 A file is divided into sublock, each represent << 11 All levels included the ground state are liste << 12 Each sublock level start by a line defining th << 13 Followed by lines defining the gamma transitio << 14 << 15 The line defining an energy level of the isoto << 16 1) An integer defining the order index of the << 17 << 18 2) A string defining floating level (-,+X,+Y << 19 - string means that it is a non floating le << 20 << 21 3) Excitation energy of the level (keV) << 22 << 23 4) Level half-life (s). A -1 half-life means a << 24 << 25 5) JPi information of the level. The sign give << 26 missing in the the ENSDF files. << 27 << 28 6) n_gammas= Number of possible gammas deexcit << 29 n_gammas=O means that no gamma deexcitatio << 30 7 31 After the line defining a level, a serie of n_ << 8 http://geant4.web.cern.ch/geant4/support/download.shtml 32 n_gammas gamma deexcitation.The information co << 33 9 34 1) The order number of the daughter level. << 10 and stored in a local directory. The environment variable 35 << 11 G4LEVELGAMMADATA must then be set to point to this directory. 36 2) The energy of the gamma transition. << 12 >> 13 ************************************************** 37 14 38 3) The relative gamma emission intensity. << 15 Each line describes a de-excitation *step* from a given energy level to a lower >> 16 one (which might be the ground state). It contains data for gamma de-excitation >> 17 and internal conversion. Notice that if multiple de-excitation >> 18 channels are allowed for the starting energy level, these channels will be >> 19 described in more lines (all having the same starting level). >> 20 >> 21 >> 22 Each line contains 17 columns: >> 23 >> 24 1) Energy of the starting nuclear level (keV) >> 25 As mentioned before, it is possible to have more lines describing the same >> 26 starting level, in the case where multiple de-excitation schemes are >> 27 allowed. >> 28 >> 29 2) Energy of the transition (keV) >> 30 This is the energy difference between the initial and the final level. >> 31 >> 32 3) Gamma transition probability (Ig in %) >> 33 Note1: if the probability is less than minProbability = 1e-8%, it is forced >> 34 to be 1e-8%. >> 35 Note2: see column 7 how total branching ratio is computed. >> 36 >> 37 4) Polarity >> 38 Spin-parity variation in the transition >> 39 [never used in real simulation] >> 40 >> 41 5) Level half-life (s) >> 42 >> 43 6) Angular Momentum >> 44 Spin of the initial level >> 45 [never used in real simulation] 39 46 40 4) The multipolarity number with 1,2,3,4,5,6,7 << 47 7) Total internal conversion coefficient : alpha = Ic/Ig 41 and 100*Nx+Ny representing multipolarity t << 42 referring to E1,M1,E2,M2,E3,M3,.. For exa << 43 << 44 << 45 5) The multipolarity mixing ratio. O means tha << 46 or the multipolarity mixing ratio is not gi << 47 << 48 6) Total internal conversion coefficient : alp << 49 Note1: total transition is the sum of gamma 48 Note1: total transition is the sum of gamma de-excitation and internal 50 conversion. Therefore total branchin 49 conversion. Therefore total branching ratio is proportional to 51 (1+alpha)*Ig << 50 (1+alpha)*Ig 52 Note2: total branching ratios from a given 51 Note2: total branching ratios from a given level do not always sum up to 53 100%. They are re-normalized interna << 52 100%. They are re-normalized internally. 54 Note3: relative probabilities for gamma de- 53 Note3: relative probabilities for gamma de-excitation and internal conversion 55 are 1/(1+alpha) and alpha/(1+alpha) 54 are 1/(1+alpha) and alpha/(1+alpha) respectively 56 7-16) Given only if total internal conversion << 55 57 Partial conversion probabilities for << 56 8-17) Partial conversion probabilities for 58 K-shell << 57 K-shell 59 L1-3 shells << 58 L1-3 shells 60 M1-5 shells << 59 M1-5 shells 61 Outer shells (shellID = 9 is u << 60 Outer shells (shellID = 9 is used, when applicable) 62 << 61 >> 62 Note: if the nuclear excitation energy does not match any of the known levels, >> 63 the *nearest* level is always considered. In G4RadioactiveDecay, >> 64 metastable states are treated correctly if the excitation energy is >> 65 within 2.0 keV of the values in $G4RADIOACTIVEDATA. >> 66 >> 67 For instance: take file $G4LEVELGAMMADATA/z28.a60 (Ni-60) >> 68 Co-60 radioactive decay populates the 1332.5080-keV level of >> 69 Ni-60 (0.12%) or the 2505.7480-keV level of Ni-60 (99.88%). >> 70 >> 71 Deexcitation from the 2505.7480-keV level is described in lines >> 72 6-8 of $G4LEVELGAMMADATA/z28.a60 (Ni-60) >> 73 Here, internal conversion coefficients are negligeable (column 7) >> 74 Therefore the nucleus will release >> 75 1) 347 keV with 7.6e-3% probability, ending up in the 2158-keV level >> 76 (following de-excitation hence takes place, lines 2-4 of the file) >> 77 2) 1173 keV with 100% probability, ending up in the 1332-keV >> 78 excited state (following de-excitation hence takes place, line 1) >> 79 3) 2505 keV with 2e-6% probability ending up in the ground state. >> 80 63 81