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Geant4/processes/hadronic/cross_sections/src/G4IonsShenCrossSection.cc

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Diff markup

Differences between /processes/hadronic/cross_sections/src/G4IonsShenCrossSection.cc (Version 11.3.0) and /processes/hadronic/cross_sections/src/G4IonsShenCrossSection.cc (Version 9.1)


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 25 //                                                 25 //
 26 // 18-Sep-2003 First version is written by T.      26 // 18-Sep-2003 First version is written by T. Koi
 27 // 12-Nov-2003 Add energy check at lower side      27 // 12-Nov-2003 Add energy check at lower side T. Koi
 28 // 15-Nov-2006 Above 10GeV/n Cross Section bec     28 // 15-Nov-2006 Above 10GeV/n Cross Section become constant T. Koi (SLAC/SCCS)
 29 // 23-Dec-2006 Isotope dependence adde by D. W     29 // 23-Dec-2006 Isotope dependence adde by D. Wright
 30 // 14-Mar-2011 Moved constructor, destructor a << 
 31 // 19-Aug-2011 V.Ivanchenko move to new design << 
 32 //                                                 30 //
 33                                                    31 
 34 #include "G4IonsShenCrossSection.hh"               32 #include "G4IonsShenCrossSection.hh"
 35 #include "G4PhysicalConstants.hh"              <<  33 #include "G4ParticleTable.hh"
 36 #include "G4SystemOfUnits.hh"                  <<  34 #include "G4IonTable.hh"
 37 #include "G4DynamicParticle.hh"                << 
 38 #include "G4NucleiProperties.hh"               << 
 39 #include "G4HadTmpUtil.hh"                     << 
 40 #include "G4NistManager.hh"                    << 
 41                                                << 
 42 G4IonsShenCrossSection::G4IonsShenCrossSection << 
 43   : G4VCrossSectionDataSet("IonsShen"),        << 
 44     upperLimit( 10*GeV ),                      << 
 45 //  lowerLimit( 10*MeV ),                      << 
 46     r0 ( 1.1 )                                 << 
 47 {}                                             << 
 48                                                    35 
 49 G4IonsShenCrossSection::~G4IonsShenCrossSectio << 
 50 {}                                             << 
 51                                                << 
 52 void                                           << 
 53 G4IonsShenCrossSection::CrossSectionDescriptio << 
 54 {                                              << 
 55   outFile << "G4IonsShenCrossSection calculate << 
 56           << "section for nucleus-nucleus scat << 
 57           << "parameterization.  It is valid f << 
 58           << "all Z, and projectile energies u << 
 59           << "the cross section is constant.   << 
 60           << "is returned.\n";                 << 
 61 }                                              << 
 62                                                << 
 63 G4bool G4IonsShenCrossSection::IsElementApplic << 
 64                G4int, const G4Material*)       << 
 65 {                                              << 
 66   return (1 <= aDP->GetDefinition()->GetBaryon << 
 67 }                                              << 
 68                                                << 
 69 G4double                                       << 
 70 G4IonsShenCrossSection::GetElementCrossSection << 
 71                  G4int Z,                      << 
 72                  const G4Material*)            << 
 73 {                                              << 
 74   G4int A = G4lrint(G4NistManager::Instance()- << 
 75   return GetIsoCrossSection(aParticle, Z, A);  << 
 76 }                                              << 
 77                                                << 
 78 G4double G4IonsShenCrossSection::GetIsoCrossSe << 
 79                 G4int Zt, G4int At,            << 
 80                 const G4Isotope*,              << 
 81                 const G4Element*,              << 
 82                 const G4Material*)             << 
 83                                                    36 
                                                   >>  37 G4double G4IonsShenCrossSection::
                                                   >>  38 GetIsoZACrossSection(const G4DynamicParticle* aParticle, G4double ZZ, 
                                                   >>  39                 G4double AA, G4double /*temperature*/)
 84 {                                                  40 {
 85    G4double xsection = 0.0;                        41    G4double xsection = 0.0;
 86                                                    42 
 87    G4int Ap = aParticle->GetDefinition()->GetB     43    G4int Ap = aParticle->GetDefinition()->GetBaryonNumber();
 88    G4int Zp = G4lrint(aParticle->GetDefinition <<  44    G4int Zp = int ( aParticle->GetDefinition()->GetPDGCharge() / eplus + 0.5 ); 
 89    G4double ke_per_N = aParticle->GetKineticEn     45    G4double ke_per_N = aParticle->GetKineticEnergy() / Ap; 
 90    if ( ke_per_N > upperLimit ) { ke_per_N = u <<  46    if ( ke_per_N > 10*GeV ) ke_per_N = 10*GeV;
 91                                                    47 
 92    // Apply energy check, if less than lower l <<  48 // Apply energy check, if less than lower limit then 0 value is returned
 93    //if (  ke_per_N < lowerLimit ) { return xs <<  49    if (  ke_per_N < lowerLimit )
                                                   >>  50       return xsection;
 94                                                    51 
 95    G4Pow* g4pow = G4Pow::GetInstance();        <<  52    G4int At = G4int(AA);
 96                                                <<  53    G4int Zt = G4int(ZZ);
 97    G4double cubicrAt = g4pow->Z13(At);         << 
 98    G4double cubicrAp = g4pow->Z13(Ap);         << 
 99                                                    54  
                                                   >>  55    G4double one_third = 1.0 / 3.0;
                                                   >>  56 
                                                   >>  57    G4double cubicrAt = std::pow ( G4double(At) , G4double(one_third) );  
                                                   >>  58    G4double cubicrAp = std::pow ( G4double(Ap) , G4double(one_third) );  
                                                   >>  59 
100    G4double Rt = 1.12 * cubicrAt - 0.94 * ( 1.     60    G4double Rt = 1.12 * cubicrAt - 0.94 * ( 1.0 / cubicrAt );
101    G4double Rp = 1.12 * cubicrAp - 0.94 * ( 1.     61    G4double Rp = 1.12 * cubicrAp - 0.94 * ( 1.0 / cubicrAp );
102                                                    62 
103    G4double r = Rt + Rp + 3.2;   // in fm          63    G4double r = Rt + Rp + 3.2;   // in fm
104    G4double b = 1.0;   // in MeV/fm                64    G4double b = 1.0;   // in MeV/fm
105    G4double targ_mass = G4NucleiProperties::Ge << 
106                                                << 
107    G4double proj_mass = aParticle->GetMass();  << 
108    G4double proj_momentum = aParticle->GetMome << 
109                                                << 
110    G4double Ecm = calEcmValue (proj_mass, targ << 
111                                                    65 
112    G4double B = 1.44 * Zt * Zp / r - b * Rt *      66    G4double B = 1.44 * Zt * Zp / r - b * Rt * Rp / ( Rt + Rp ); 
113    if(Ecm <= B) { return xsection; }           <<  67 
                                                   >>  68    //G4double ke_per_N = aParticle->GetKineticEnergy() / Ap; 
114                                                    69 
115    G4double c = calCeValue ( ke_per_N / MeV  )     70    G4double c = calCeValue ( ke_per_N / MeV  );  
116                                                    71 
117    G4double R1 = r0 * (cubicrAt + cubicrAp + 1 <<  72    G4double R1 = r0 * ( cubicrAt + cubicrAp + 1.85 * cubicrAt * cubicrAp / ( cubicrAt + cubicrAp ) - c); 
118                                                    73 
119    G4double R2 = 1.0 * ( At - 2 * Zt ) * Zp /      74    G4double R2 = 1.0 * ( At - 2 * Zt ) * Zp / ( Ap * At );
120                                                    75 
                                                   >>  76    G4double targ_mass = G4ParticleTable::GetParticleTable()->GetIonTable()->GetIonMass( Zt , At );
                                                   >>  77    G4double proj_mass = aParticle->GetMass();
                                                   >>  78    G4double proj_momentum = aParticle->GetMomentum().mag();
                                                   >>  79 
                                                   >>  80    G4double Ecm = calEcmValue ( proj_mass , targ_mass , proj_momentum ); 
121                                                    81 
122    G4double R3 = (0.176 / g4pow->A13(Ecm)) * c <<  82    G4double R3 = 0.176 / std::pow ( G4double(Ecm) , G4double(one_third) ) * cubicrAt * cubicrAp / ( cubicrAt + cubicrAp );
123                                                    83 
124    G4double R = R1 + R2 + R3;                      84    G4double R = R1 + R2 + R3;
125                                                    85 
126    xsection = 10 * pi * R * R * ( 1 - B / Ecm      86    xsection = 10 * pi * R * R * ( 1 - B / Ecm );   
127    xsection = xsection * millibarn;   // mulit <<  87    xsection = xsection * millibarn;   // mulitply xsection by millibarn    
128                                                <<  88   
129    return xsection;                                89    return xsection; 
130 }                                                  90 }
131                                                    91 
132 G4double                                       <<  92 
133 G4IonsShenCrossSection::calEcmValue(const G4do <<  93 G4double G4IonsShenCrossSection::
134                                     const G4do <<  94 GetCrossSection(const G4DynamicParticle* aParticle, const G4Element* anElement,
                                                   >>  95                 G4double temperature)
                                                   >>  96 {
                                                   >>  97   G4int nIso = anElement->GetNumberOfIsotopes();
                                                   >>  98   G4double xsection = 0;
                                                   >>  99    
                                                   >> 100   if (nIso) {
                                                   >> 101     G4double sig;
                                                   >> 102     G4IsotopeVector* isoVector = anElement->GetIsotopeVector();
                                                   >> 103     G4double* abundVector = anElement->GetRelativeAbundanceVector();
                                                   >> 104     G4double ZZ;
                                                   >> 105     G4double AA;
                                                   >> 106    
                                                   >> 107     for (G4int i = 0; i < nIso; i++) {
                                                   >> 108       ZZ = G4double( (*isoVector)[i]->GetZ() );
                                                   >> 109       AA = G4double( (*isoVector)[i]->GetN() );
                                                   >> 110       sig = GetIsoZACrossSection(aParticle, ZZ, AA, temperature);
                                                   >> 111       xsection += sig*abundVector[i];
                                                   >> 112     }
                                                   >> 113  
                                                   >> 114   } else {
                                                   >> 115     xsection =
                                                   >> 116       GetIsoZACrossSection(aParticle, anElement->GetZ(), anElement->GetN(), 
                                                   >> 117                            temperature);
                                                   >> 118   }
                                                   >> 119   
                                                   >> 120   return xsection;
                                                   >> 121 }
                                                   >> 122 
                                                   >> 123 
                                                   >> 124 G4double G4IonsShenCrossSection::calEcmValue( const G4double mp , const G4double mt , const G4double Plab )
135 {                                                 125 {
136    G4double Elab = std::sqrt ( mp * mp + Plab     126    G4double Elab = std::sqrt ( mp * mp + Plab * Plab );
137    G4double Ecm = std::sqrt ( mp * mp + mt * m    127    G4double Ecm = std::sqrt ( mp * mp + mt * mt + 2 * Elab * mt );
138    G4double Pcm = Plab * mt / Ecm;                128    G4double Pcm = Plab * mt / Ecm;
139    G4double KEcm = std::sqrt ( Pcm * Pcm + mp     129    G4double KEcm = std::sqrt ( Pcm * Pcm + mp * mp ) - mp;
140    return KEcm;                                   130    return KEcm;
141 }                                                 131 }
142                                                   132 
143                                                   133 
144 G4double G4IonsShenCrossSection::calCeValue(co << 134 G4double G4IonsShenCrossSection::calCeValue( const G4double ke )
145 {                                                 135 {
146   // Calculate c value                         << 136    // Calculate c value 
147   // This value is indepenent from projectile  << 137    // This value is indepenent from projectile and target particle 
148   // ke is projectile kinetic energy per nucle << 138    // ke is projectile kinetic energy per nucleon in the Lab system with MeV unit 
149   // with MeV unit                             << 139    // fitting function is made by T. Koi 
150   // fitting function is made by T. Koi        << 140    // There are no data below 30 MeV/n in Kox et al., 
151   // There are no data below 30 MeV/n in Kox e << 
152                                                   141 
153    G4double Ce;                                   142    G4double Ce; 
154    G4double log10_ke = std::log10 ( ke );         143    G4double log10_ke = std::log10 ( ke );   
155    if (log10_ke > 1.5)                         << 144    if ( log10_ke > 1.5 ) 
156    {                                              145    {
157      Ce = -10.0/std::pow(G4double(log10_ke), G << 146       Ce = - 10.0 / std::pow ( G4double(log10_ke) , G4double(5) ) + 2.0;
158    }                                              147    }
159    else                                           148    else
160    {                                              149    {
161      Ce = (-10.0/std::pow(G4double(1.5), G4dou << 150       Ce = ( - 10.0 / std::pow ( G4double(1.5) , G4double(5) ) + 2.0 ) / std::pow ( G4double(1.5) , G4double(3) ) * std::pow ( G4double(log10_ke) , G4double(3) );
162          std::pow(G4double(1.5) , G4double(3)) << 
163    }                                              151    }
164    return Ce;                                     152    return Ce;
165 }                                                 153 }
166                                                << 
167                                                   154