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 Environment variable "G4FORCE_RUN_MANAGER_TYPE" enabled with value == Serial. Forcing G4RunManager type...
 
         ############################################
         !!! WARNING - FPE detection is activated !!!
         ############################################
 
 
           ################################
           !!! G4Backtrace is activated !!!
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 **************************************************************
  Geant4 version Name: geant4-11-03-ref-06    (30-June-2025)
                        Copyright : Geant4 Collaboration
                       References : NIM A 506 (2003), 250-303
                                  : IEEE-TNS 53 (2006), 270-278
                                  : NIM A 835 (2016), 186-225
                              WWW : http://geant4.org/
 **************************************************************
 
 <<< Geant4 Physics List simulation engine: FTFP_BERT
 
  constructing parallel world 
  B02ImportanceDetectorConstruction:: ghostWorldName = ParallelBiasingWorld
 --- G4CoupledTransportation is used 
 
  hInelastic FTFP_BERT : threshold between BERT and FTFP is over the interval 
  for pions :   3 to 6 GeV
  for kaons :   3 to 6 GeV
  for proton :  3 to 6 GeV
  for neutron : 3 to 6 GeV
 
 ### Adding tracking cuts for neutron  TimeCut(ns)= 10000  KinEnergyCut(MeV)= 0
  paraFlag: 1
  Preparing Importance Sampling 
 G4IStore:: Creating new Parallel IStore ParallelBiasingWorld
  G4IStore:: ParallelWorldName = ParallelBiasingWorld
  G4IStore:: fParallelWorldVolume = ParallelBiasingWorld
 G4GeometrySampler:: preparing importance sampling WorldName is 
  G4ImportanceConfigurator:: setting world name: 
 G4ImportanceConfigurator:: entering importance configure, paraflag 1
 ### G4ImportanceProcess:: Creating 
 G4ImportanceProcess:: importance process paraflag is: 1
 
 
 
 G4ImportanceProcess:: SetParallelWorld name = ParallelBiasingWorld
 === G4ProcessPlacer::AddProcessAsSecondDoIt: for: neutron
   Modifying Process Order for ProcessName: ImportanceProcess
   The initial AlongStep Vectors: 
 GPIL Vector: 
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
 The initial PostStep Vectors: 
 GPIL Vector: 
    nKiller
    nCapture
    neutronInelastic
    hadElastic
    Decay
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
    Decay
    hadElastic
    neutronInelastic
    nCapture
    nKiller
   The final AlongStep Vectors: 
 GPIL Vector: 
    ImportanceProcess
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
    ImportanceProcess
 The final PostStep Vectors: 
 GPIL Vector: 
    nKiller
    nCapture
    neutronInelastic
    hadElastic
    Decay
    ImportanceProcess
    CoupledTransportation
 DoIt Vector: 
    CoupledTransportation
    ImportanceProcess
    Decay
    hadElastic
    neutronInelastic
    nCapture
    nKiller
 ================================================
  B02ImportanceDetectorConstruction:: Creating Importance Store 
  adding cell: 1 replica: 0 name: cell_01
 Going to assign importance: 1, to volume: cell_01
  adding cell: 2 replica: 0 name: cell_02
 Going to assign importance: 2, to volume: cell_02
  adding cell: 3 replica: 0 name: cell_03
 Going to assign importance: 4, to volume: cell_03
  adding cell: 4 replica: 0 name: cell_04
 Going to assign importance: 8, to volume: cell_04
  adding cell: 5 replica: 0 name: cell_05
 Going to assign importance: 16, to volume: cell_05
  adding cell: 6 replica: 0 name: cell_06
 Going to assign importance: 32, to volume: cell_06
  adding cell: 7 replica: 0 name: cell_07
 Going to assign importance: 64, to volume: cell_07
  adding cell: 8 replica: 0 name: cell_08
 Going to assign importance: 128, to volume: cell_08
  adding cell: 9 replica: 0 name: cell_09
 Going to assign importance: 256, to volume: cell_09
  adding cell: 10 replica: 0 name: cell_10
 Going to assign importance: 512, to volume: cell_10
  adding cell: 11 replica: 0 name: cell_11
 Going to assign importance: 1024, to volume: cell_11
  adding cell: 12 replica: 0 name: cell_12
 Going to assign importance: 2048, to volume: cell_12
  adding cell: 13 replica: 0 name: cell_13
 Going to assign importance: 4096, to volume: cell_13
  adding cell: 14 replica: 0 name: cell_14
 Going to assign importance: 8192, to volume: cell_14
  adding cell: 15 replica: 0 name: cell_15
 Going to assign importance: 16384, to volume: cell_15
  adding cell: 16 replica: 0 name: cell_16
 Going to assign importance: 32768, to volume: cell_16
  adding cell: 17 replica: 0 name: cell_17
 Going to assign importance: 65536, to volume: cell_17
  adding cell: 18 replica: 0 name: cell_18
 Going to assign importance: 131072, to volume: cell_18
 =======================================================================
 ======                 Electromagnetic Physics Parameters      ========
 =======================================================================
 LPM effect enabled                                 1
 Enable creation and use of sampling tables         0
 Apply cuts on all EM processes                     0
 Use combined TransportationWithMsc                 Disabled
 Use general process                                1
 Enable linear polarisation for gamma               0
 Enable photoeffect sampling below K-shell          1
 Enable sampling of quantum entanglement            0
 X-section factor for integral approach             0.8
 Min kinetic energy for tables                      100 eV 
 Max kinetic energy for tables                      100 TeV
 Number of bins per decade of a table               7
 Verbose level                                      1
 Verbose level for worker thread                    0
 Bremsstrahlung energy threshold above which 
   primary e+- is added to the list of secondary    100 TeV
 Bremsstrahlung energy threshold above which primary
   muon/hadron is added to the list of secondary    100 TeV
 Positron annihilation at rest model                SimplePositronium
 Enable 3 gamma annihilation on fly                 0
 Lowest triplet kinetic energy                      1 MeV
 Enable sampling of gamma linear polarisation       0
 5D gamma conversion model type                     0
 5D gamma conversion model on isolated ion          0
 Use RiGe 5D e+e- pair production model by muons    0
 Livermore data directory                           epics_2017
 =======================================================================
 ======                 Ionisation Parameters                   ========
 =======================================================================
 Step function for e+-                              (0.2, 1 mm)
 Step function for muons/hadrons                    (0.2, 0.1 mm)
 Step function for light ions                       (0.2, 0.1 mm)
 Step function for general ions                     (0.2, 0.1 mm)
 Lowest e+e- kinetic energy                         1 keV
 Lowest muon/hadron kinetic energy                  1 keV
 Use ICRU90 data                                    0
 Fluctuations of dE/dx are enabled                  1
 Type of fluctuation model for leptons and hadrons  Urban
 Use built-in Birks satuaration                     0
 Build CSDA range enabled                           0
 Use cut as a final range enabled                   0
 Enable angular generator interface                 0
 Max kinetic energy for CSDA tables                 1 GeV
 Max kinetic energy for NIEL computation            0 eV 
 Linear loss limit                                  0.01
 Read data from file for e+e- pair production by mu 0
 =======================================================================
 ======                 Multiple Scattering Parameters          ========
 =======================================================================
 Type of msc step limit algorithm for e+-           1
 Type of msc step limit algorithm for muons/hadrons 0
 Msc lateral displacement for e+- enabled           1
 Msc lateral displacement for muons and hadrons     0
 Urban msc model lateral displacement alg96         1
 Range factor for msc step limit for e+-            0.04
 Range factor for msc step limit for muons/hadrons  0.2
 Geometry factor for msc step limitation of e+-     2.5
 Safety factor for msc step limit for e+-           0.6
 Skin parameter for msc step limitation of e+-      1
 Lambda limit for msc step limit for e+-            1 mm
 Use Mott correction for e- scattering              0
 Factor used for dynamic computation of angular 
   limit between single and multiple scattering     1
 Fixed angular limit between single 
   and multiple scattering                          3.1416 rad
 Upper energy limit for e+- multiple scattering     100 MeV
 Type of electron single scattering model           0
 Type of nuclear form-factor                        1
 Screening factor                                   1
 =======================================================================
 
 phot:  for gamma SubType=12 BuildTable=0
       LambdaPrime table from 200 keV to 100 TeV in 61 bins 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
  LivermorePhElectric : Emin=    0 eV  Emax=  100 TeV  SauterGavrila Fluo
 
 compt:  for gamma SubType=13 BuildTable=1
       Lambda table from 100 eV  to 1 MeV, 7 bins/decade, spline: 1
       LambdaPrime table from 1 MeV to 100 TeV in 56 bins 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
        Klein-Nishina : Emin=    0 eV  Emax=  100 TeV
 
 conv:  for gamma SubType=14 BuildTable=1
       Lambda table from 1.022 MeV to 100 TeV, 18 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
      BetheHeitlerLPM : Emin=    0 eV  Emax=  100 TeV  ModifiedTsai
 
 Rayl:  for gamma SubType=11 BuildTable=1
       Lambda table from 100 eV  to 150 keV, 7 bins/decade, spline: 0
       LambdaPrime table from 150 keV to 100 TeV in 62 bins 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
    LivermoreRayleigh : Emin=    0 eV  Emax=  100 TeV  CullenGenerator
 
 msc:  for e-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 MeV Nbins=42 100 eV  - 100 MeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
         WentzelVIUni : Emin=  100 MeV Emax=  100 TeV Nbins=42 100 MeV - 100 TeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
 
 eIoni:  for e-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         MollerBhabha : Emin=    0 eV  Emax=  100 TeV
 
 eBrem:  for e-  XStype:4  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       LPM flag: 1 for E > 1 GeV,  VertexHighEnergyTh(GeV)= 100000
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
              eBremSB : Emin=    0 eV  Emax=    1 GeV  ModifiedTsai
             eBremLPM : Emin=    1 GeV Emax=  100 TeV  ModifiedTsai
 
 CoulombScat:  for e- XStype:1 SubType=1 BuildTable=1
       Lambda table from 100 MeV to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=  100 MeV Emax=  100 TeV
 
 msc:  for e+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 MeV Nbins=42 100 eV  - 100 MeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
         WentzelVIUni : Emin=  100 MeV Emax=  100 TeV Nbins=42 100 MeV - 100 TeV
           StepLim=UseSafety Rfact=0.04 Gfact=2.5 Sfact=0.6 DispFlag:1 Skin=1 Llim=1 mm
 
 eIoni:  for e+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         MollerBhabha : Emin=    0 eV  Emax=  100 TeV
 
 eBrem:  for e+  XStype:4  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       LPM flag: 1 for E > 1 GeV,  VertexHighEnergyTh(GeV)= 100000
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
              eBremSB : Emin=    0 eV  Emax=    1 GeV  ModifiedTsai
             eBremLPM : Emin=    1 GeV Emax=  100 TeV  ModifiedTsai
 
 annihil:  for e+ XStype:2 SubType=5 AtRestModel:Simple BuildTable=0
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             eplus2gg : Emin=    0 eV  Emax=  100 TeV
 
 CoulombScat:  for e+ XStype:1 SubType=1 BuildTable=1
       Lambda table from 100 MeV to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=  100 MeV Emax=  100 TeV
 
 msc:  for proton  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for proton  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=    2 MeV
           BetheBloch : Emin=    2 MeV Emax=  100 TeV
 
 hBrems:  for proton  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for proton  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 17x1001 from 7.50618 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for proton XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for GenericIon  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 ionIoni:  for GenericIon  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.02
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=    2 MeV
           BetheBloch : Emin=    2 MeV Emax=  100 TeV
 
 msc:  for alpha  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             UrbanMsc : Emin=    0 eV  Emax=  100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 ionIoni:  for alpha  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.02
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             BraggIon : Emin=    0 eV  Emax=7.9452 MeV
           BetheBloch : Emin=7.9452 MeV Emax=  100 TeV
 
 msc:  for anti_proton  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for anti_proton  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=    2 MeV
           BetheBloch : Emin=    2 MeV Emax=  100 TeV
 
 hBrems:  for anti_proton  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for anti_proton  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 17x1001 from 7.50618 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for anti_proton XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for kaon+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for kaon+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=1.05231 MeV
           BetheBloch : Emin=1.05231 MeV Emax=  100 TeV
 
 hBrems:  for kaon+  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for kaon+  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 18x1001 from 3.94942 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for kaon+ XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for kaon-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for kaon-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=1.05231 MeV
           BetheBloch : Emin=1.05231 MeV Emax=  100 TeV
 
 hBrems:  for kaon-  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for kaon-  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 18x1001 from 3.94942 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for kaon- XStype:1 SubType=1 BuildTable=1
       Used Lambda table of kaon+
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for mu+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 muIoni:  for mu+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=  200 keV
         MuBetheBloch : Emin=  200 keV Emax=  100 TeV
 
 muBrems:  for mu+  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
               MuBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 muPairProd:  for mu+  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 21x1001 from 0.85 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
           muPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for mu+ XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for mu-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 muIoni:  for mu-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=  200 keV
         MuBetheBloch : Emin=  200 keV Emax=  100 TeV
 
 muBrems:  for mu-  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
               MuBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 muPairProd:  for mu-  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 21x1001 from 0.85 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
           muPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for mu- XStype:1 SubType=1 BuildTable=1
       Used Lambda table of mu+
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for pi+  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for pi+  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                Bragg : Emin=    0 eV  Emax=297.505 keV
           BetheBloch : Emin=297.505 keV Emax=  100 TeV
 
 hBrems:  for pi+  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for pi+  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 20x1001 from 1.11656 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for pi+ XStype:1 SubType=1 BuildTable=1
       Lambda table from threshold  to 100 TeV, 7 bins/decade, spline: 0
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 msc:  for pi-  SubType= 10
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
         WentzelVIUni : Emin=    0 eV  Emax=  100 TeV Nbins=84 100 eV  - 100 TeV
           StepLim=Minimal Rfact=0.2 Gfact=2.5 Sfact=0.6 DispFlag:0 Skin=1 Llim=1 mm
 
 hIoni:  for pi-  XStype:3  SubType=2
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       StepFunction=(0.2, 0.1 mm), integ: 3, fluct: 1, linLossLim= 0.01
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
             ICRU73QO : Emin=    0 eV  Emax=297.505 keV
           BetheBloch : Emin=297.505 keV Emax=  100 TeV
 
 hBrems:  for pi-  XStype:1  SubType=3
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
                hBrem : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 hPairProd:  for pi-  XStype:1  SubType=4
       dE/dx and range tables from 100 eV  to 100 TeV in 84 bins
       Lambda tables from threshold to 100 TeV, 7 bins/decade, spline: 1
       Sampling table 20x1001 from 1.11656 GeV to 100 TeV 
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
            hPairProd : Emin=    0 eV  Emax=  100 TeV  ModifiedMephi
 
 CoulombScat:  for pi- XStype:1 SubType=1 BuildTable=1
       Used Lambda table of pi+
       ThetaMin(p) < Theta(degree) < 180, pLimit(GeV^1)= 0.139531
       ===== EM models for the G4Region  DefaultRegionForTheWorld ======
   eCoulombScattering : Emin=    0 eV  Emax=  100 TeV
 
 ====================================================================
                   HADRONIC PROCESSES SUMMARY (verbose level 1)
 -----------------------------------------------------------------------
                            Hadronic Processes for neutron
   Process: hadElastic
         Model:             hElasticCHIPS: 0 eV  ---> 100 TeV
      Cr_sctns:        G4NeutronElasticXS: 0 eV  ---> 100 TeV
   Process: neutronInelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:      G4NeutronInelasticXS: 0 eV  ---> 100 TeV
   Process: nCapture
         Model:               nRadCapture: 0 eV  ---> 100 TeV
      Cr_sctns:        G4NeutronCaptureXS: 0 eV  ---> 100 TeV
   Process: nKiller
 -----------------------------------------------------------------------
                            Hadronic Processes for B-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: B-Inelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for D-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: D-Inelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for GenericIon
   Process: ionInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for He3
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: He3Inelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for alpha
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: alphaInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_He3
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_He3Inelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_alpha
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_alphaInelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_deuteron
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_deuteronInelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -------------------------------------------------------------------------
                            Hadronic Processes for anti_hypertriton
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_lambda
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: anti_lambdaInelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_neutron
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100.1 MeV
         Model:              AntiAElastic: 100 MeV ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_neutronInelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_proton
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100.1 MeV
         Model:              AntiAElastic: 100 MeV ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_protonInelastic
         Model:                      FTFP: 0 eV  ---> 100 TeV
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for anti_triton
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100.1 MeV/n
         Model:              AntiAElastic: 100 MeV/n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: anti_tritonInelastic
         Model:                      FTFP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:              AntiAGlauber: 0 eV  ---> 25.6 PeV
   Process: hFritiofCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for deuteron
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: dInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 -----------------------------------------------------------------------
                            Hadronic Processes for e+
   Process: positronNuclear
         Model:   G4ElectroVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:          ElectroNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for e-
   Process: electronNuclear
         Model:   G4ElectroVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:          ElectroNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for gamma
   Process: photonNuclear
         Model:               GammaNPreco: 0 eV  ---> 200 MeV
         Model:            BertiniCascade: 199 MeV ---> 6 GeV
         Model:           TheoFSGenerator: 3 GeV ---> 100 TeV
      Cr_sctns:            GammaNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for kaon+
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: kaon+Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for kaon-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: kaon-Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: hBertiniCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for lambda
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: lambdaInelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for mu+
   Process: muonNuclear
         Model:      G4MuonVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:     KokoulinMuonNuclearXS: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for mu-
   Process: muonNuclear
         Model:      G4MuonVDNuclearModel: 0 eV  ---> 1 PeV
      Cr_sctns:     KokoulinMuonNuclearXS: 0 eV  ---> 100 TeV
   Process: muMinusCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for pi+
   Process: hadElastic
         Model:           hElasticGlauber: 0 eV  ---> 100 TeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: pi+Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for pi-
   Process: hadElastic
         Model:           hElasticGlauber: 0 eV  ---> 100 TeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: pi-Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: hBertiniCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for proton
   Process: hadElastic
         Model:             hElasticCHIPS: 0 eV  ---> 100 TeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
   Process: protonInelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:  BarashenkovGlauberGribov: 0 eV  ---> 100 TeV
 -----------------------------------------------------------------------
                            Hadronic Processes for sigma-
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV  ---> 100 TeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: sigma-Inelastic
         Model:                      FTFP: 3 GeV ---> 100 TeV
         Model:            BertiniCascade: 0 eV  ---> 6 GeV
      Cr_sctns:            Glauber-Gribov: 0 eV  ---> 100 TeV
   Process: hBertiniCaptureAtRest
 -----------------------------------------------------------------------
                            Hadronic Processes for triton
   Process: hadElastic
         Model:              hElasticLHEP: 0 eV /n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
   Process: tInelastic
         Model:  Binary Light Ion Cascade: 0 eV /n ---> 6 GeV/n
         Model:                      FTFP: 3 GeV/n ---> 100 TeV/n
      Cr_sctns:  Glauber-Gribov Nucl-nucl: 0 eV  ---> 25.6 PeV
 =======================================================================
 ======       Geant4 Native Pre-compound Model Parameters       ========
 =======================================================================
 Type of pre-compound model                          0
 Type of pre-compound inverse x-section              1
 Pre-compound model active                           1
 Pre-compound excitation low energy                  100 keV
 Pre-compound excitation high energy                 30 MeV
 Angular generator for pre-compound model            1
 Use NeverGoBack option for pre-compound model       0
 Use SoftCutOff option for pre-compound model        0
 Use CEM transitions for pre-compound model          1
 Use GNASH transitions for pre-compound model        0
 Use HETC submodel for pre-compound model            0
 =======================================================================
 ======       Nuclear De-excitation Module Parameters           ========
 =======================================================================
 Type of de-excitation inverse x-section             3
 Type of de-excitation factory                       Evaporation+GEM
 Number of de-excitation channels                    68
 Type of Fermi BreakUp model                         ModelVI
 Min excitation energy                               10 eV 
 Min energy per nucleon for multifragmentation       200 GeV
 Limit excitation energy for Fermi BreakUp           20 MeV
 Level density (1/MeV)                               0.075
 Use simple level density model                      1
 Use discrete excitation energy of the residual      0
 Time limit for long lived isomeres                  1 ns 
 Isomer production flag                              1
 Internal e- conversion flag                         1
 Store e- internal conversion data                   1
 Correlated gamma emission flag                      0
 Max 2J for sampling of angular correlations         10
 =======================================================================
 ++ ConcreteSD/Collisions id 0
 ++ ConcreteSD/CollWeight id 1
 ++ ConcreteSD/Population id 2
 ++ ConcreteSD/TrackEnter id 3
 ++ ConcreteSD/SL id 4
 ++ ConcreteSD/SLW id 5
 ++ ConcreteSD/SLWE id 6
 ++ ConcreteSD/SLW_V id 7
 ++ ConcreteSD/SLWE_V id 8
 ### Run 0 start.
  ###### EndOfRunAction  
 
 --------------------End of Global Run-----------------------
  Number of event processed : 100
 =============================================================
 =============================================================
         Volume |   Tr.Entering |    Population |    Collisions |      Coll*WGT |     NumWGTedE |    FluxWGTedE |     Av.Tr.WGT |            SL |           SLW |         SLW_v |          SLWE |        SLWE_v |
        cell_00 |            45 |           137 |             0 |             0 |      0.192848 |       3.12656 |             1 |       9549.94 |       9549.94 |       5608.38 |       29858.5 |       1081.56 |
        cell_01 |           144 |           178 |           388 |           388 |     0.0186455 |       5.07451 |             1 |       23641.7 |       23641.7 |        178648 |        119970 |       3330.99 |
        cell_02 |           165 |           255 |          1504 |           752 |     0.0092135 |        2.5341 |           0.5 |       50775.8 |       25387.9 |        225157 |       64335.4 |       2074.49 |
        cell_03 |           206 |           324 |          1859 |        464.75 |    0.00624517 |       1.92716 |          0.25 |       62866.9 |       15716.7 |        171366 |       30288.7 |       1070.21 |
        cell_04 |           253 |           385 |          2051 |       256.375 |    0.00556523 |       1.64061 |         0.125 |       66537.4 |       8317.17 |       93132.5 |       13645.2 |       518.304 |
        cell_05 |           303 |           443 |          2609 |       163.062 |    0.00370969 |       1.52672 |        0.0625 |       82318.1 |       5144.88 |       82717.1 |       7854.81 |       306.855 |
        cell_06 |           312 |           464 |          3265 |       102.031 |    0.00350066 |       1.20523 |       0.03125 |       94242.9 |       2945.09 |       41148.9 |       3549.52 |       144.048 |
        cell_07 |           316 |           458 |          3171 |       49.5469 |    0.00335235 |       1.17561 |      0.015625 |       91651.9 |       1432.06 |       20684.8 |       1683.54 |       69.3427 |
        cell_08 |           308 |           421 |          2763 |       21.5859 |    0.00298094 |       1.22732 |     0.0078125 |       80097.8 |       625.764 |       10464.5 |       768.014 |       31.1941 |
        cell_09 |           316 |           449 |          3053 |       11.9258 |    0.00327999 |       1.19199 |    0.00390625 |       87053.3 |       340.052 |       5140.98 |        405.34 |       16.8623 |
        cell_10 |           331 |           454 |          2878 |       5.62109 |    0.00268567 |       1.14499 |    0.00195312 |       84451.7 |       164.945 |       2895.04 |       188.861 |       7.77513 |
        cell_11 |           279 |           396 |          2820 |       2.75391 |    0.00236844 |      0.910882 |   0.000976562 |       76852.4 |       75.0512 |       1281.46 |       68.3628 |       3.03506 |
        cell_12 |           224 |           311 |          2130 |       1.04004 |    0.00296345 |       1.04813 |   0.000488281 |       61214.1 |       29.8897 |        457.91 |       31.3283 |       1.35699 |
        cell_13 |           181 |           279 |          1751 |       0.42749 |     0.0025909 |       1.07668 |   0.000244141 |         51200 |          12.5 |       219.751 |       13.4585 |      0.569352 |
        cell_14 |           151 |           231 |          1327 |      0.161987 |    0.00225236 |       1.11343 |    0.00012207 |       40154.2 |       4.90163 |       101.406 |       5.45763 |      0.228402 |
        cell_15 |           146 |           210 |          1315 |     0.0802612 |    0.00405225 |       1.17921 |   6.10352e-05 |       41655.5 |       2.54245 |        33.501 |       2.99809 |      0.135754 |
        cell_16 |           161 |           225 |          1583 |     0.0483093 |    0.00233692 |      0.866892 |   3.05176e-05 |       44606.4 |       1.36128 |       24.0028 |       1.18008 |     0.0560926 |
        cell_17 |           164 |           233 |          1495 |     0.0228119 |     0.0024936 |      0.850822 |   1.52588e-05 |       43364.6 |      0.661691 |       10.6231 |      0.562982 |     0.0264898 |
        cell_18 |            96 |           174 |          1034 |    0.00788879 |    0.00238054 |      0.968888 |   7.62939e-06 |       29751.1 |      0.226983 |        4.4227 |      0.219921 |     0.0105284 |
        cell_19 |            61 |            61 |             0 |             0 |     0.0168099 |       1.75455 |   7.62939e-06 |       9868.08 |     0.0752875 |      0.350991 |      0.132096 |    0.00590012 |
 =============================================

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