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Geant4/processes/hadronic/models/de_excitation/multifragmentation/src/G4StatMFMacroMultiNucleon.cc

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Diff markup

Differences between /processes/hadronic/models/de_excitation/multifragmentation/src/G4StatMFMacroMultiNucleon.cc (Version 11.3.0) and /processes/hadronic/models/de_excitation/multifragmentation/src/G4StatMFMacroMultiNucleon.cc (Version 10.6.p1)


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 25 //                                                 25 //
 26 //                                                 26 //
 27 //                                                 27 //
 28 // Hadronic Process: Nuclear De-excitations        28 // Hadronic Process: Nuclear De-excitations
 29 // by V. Lara                                      29 // by V. Lara
 30 //                                                 30 //
 31 // Modified:                                       31 // Modified:
 32 // 25.07.08 I.Pshenichnov (in collaboration wi     32 // 25.07.08 I.Pshenichnov (in collaboration with Alexander Botvina and Igor 
 33 //          Mishustin (FIAS, Frankfurt, INR, M     33 //          Mishustin (FIAS, Frankfurt, INR, Moscow and Kurchatov Institute, 
 34 //          Moscow, pshenich@fias.uni-frankfur     34 //          Moscow, pshenich@fias.uni-frankfurt.de) fixed computation of the 
 35 //          symmetry energy                        35 //          symmetry energy 
 36                                                    36 
 37 #include "G4StatMFMacroMultiNucleon.hh"            37 #include "G4StatMFMacroMultiNucleon.hh"
 38 #include "G4PhysicalConstants.hh"                  38 #include "G4PhysicalConstants.hh"
 39 #include "G4SystemOfUnits.hh"                      39 #include "G4SystemOfUnits.hh"
 40 #include "G4Log.hh"                                40 #include "G4Log.hh"
 41 #include "G4Exp.hh"                                41 #include "G4Exp.hh"
 42 #include "G4Pow.hh"                                42 #include "G4Pow.hh"
 43                                                    43 
 44 // Default constructor                             44 // Default constructor
 45 G4StatMFMacroMultiNucleon::                        45 G4StatMFMacroMultiNucleon::
 46 G4StatMFMacroMultiNucleon() :                      46 G4StatMFMacroMultiNucleon() :
 47     G4VStatMFMacroCluster(0)  // Beacuse the d     47     G4VStatMFMacroCluster(0)  // Beacuse the def. constr. of base class is private
 48 {                                                  48 {
 49     throw G4HadronicException(__FILE__, __LINE     49     throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroMultiNucleon::default_constructor meant to not be accessible");
 50 }                                                  50 }
 51                                                    51 
 52 // Copy constructor                                52 // Copy constructor
 53 G4StatMFMacroMultiNucleon::                        53 G4StatMFMacroMultiNucleon::
 54 G4StatMFMacroMultiNucleon(const G4StatMFMacroM     54 G4StatMFMacroMultiNucleon(const G4StatMFMacroMultiNucleon & ) :
 55     G4VStatMFMacroCluster(0)  // Beacuse the d     55     G4VStatMFMacroCluster(0)  // Beacuse the def. constr. of base class is private
 56 {                                                  56 {
 57     throw G4HadronicException(__FILE__, __LINE     57     throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroMultiNucleon::copy_constructor meant to not be accessible");
 58 }                                                  58 }
 59                                                    59 
 60 // Operators                                       60 // Operators
 61                                                    61 
 62 G4StatMFMacroMultiNucleon & G4StatMFMacroMulti     62 G4StatMFMacroMultiNucleon & G4StatMFMacroMultiNucleon::
 63 operator=(const G4StatMFMacroMultiNucleon & )      63 operator=(const G4StatMFMacroMultiNucleon & ) 
 64 {                                                  64 {
 65     throw G4HadronicException(__FILE__, __LINE     65     throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroMultiNucleon::operator= meant to not be accessible");
 66     return *this;                                  66     return *this;
 67 }                                                  67 }
 68                                                    68 
 69 G4bool G4StatMFMacroMultiNucleon::operator==(c     69 G4bool G4StatMFMacroMultiNucleon::operator==(const G4StatMFMacroMultiNucleon & ) const
 70 {                                                  70 {
 71     throw G4HadronicException(__FILE__, __LINE     71     throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroMultiNucleon::operator== meant to not be accessible");
 72     return false;                                  72     return false;
 73 }                                                  73 }
 74                                                    74  
 75 G4bool G4StatMFMacroMultiNucleon::operator!=(c     75 G4bool G4StatMFMacroMultiNucleon::operator!=(const G4StatMFMacroMultiNucleon & ) const
 76 {                                                  76 {
 77     throw G4HadronicException(__FILE__, __LINE     77     throw G4HadronicException(__FILE__, __LINE__, "G4StatMFMacroMultiNucleon::operator!= meant to not be accessible");
 78     return true;                                   78     return true;
 79 }                                                  79 }
 80                                                    80 
 81 G4double G4StatMFMacroMultiNucleon::CalcMeanMu     81 G4double G4StatMFMacroMultiNucleon::CalcMeanMultiplicity(const G4double FreeVol, 
 82                const G4double mu,                  82                const G4double mu,
 83                const G4double nu,                  83                const G4double nu, 
 84                const G4double T)                   84                const G4double T)
 85 {                                                  85 {
 86   G4double ThermalWaveLenght = 16.15*fermi/std     86   G4double ThermalWaveLenght = 16.15*fermi/std::sqrt(T);  
 87   G4double lambda3 = ThermalWaveLenght*Thermal     87   G4double lambda3 = ThermalWaveLenght*ThermalWaveLenght*ThermalWaveLenght;
 88   G4Pow* g4calc = G4Pow::GetInstance();            88   G4Pow* g4calc = G4Pow::GetInstance();
 89   G4double A23 = g4calc->Z23(theA);                89   G4double A23 = g4calc->Z23(theA);
 90                                                    90   
 91   G4double exponent = (mu + nu*theZARatio+ G4S     91   G4double exponent = (mu + nu*theZARatio+ G4StatMFParameters::GetE0() 
 92            + T*T/_InvLevelDensity                  92            + T*T/_InvLevelDensity 
 93            - G4StatMFParameters::GetGamma0()*(     93            - G4StatMFParameters::GetGamma0()*(1.0 - 2.0*theZARatio)*
 94            (1.0 - 2.0*theZARatio))*theA            94            (1.0 - 2.0*theZARatio))*theA
 95     - G4StatMFParameters::Beta(T)*A23              95     - G4StatMFParameters::Beta(T)*A23 
 96     - G4StatMFParameters::GetCoulomb()*theZARa     96     - G4StatMFParameters::GetCoulomb()*theZARatio*theZARatio*A23*theA;
 97                                                    97   
 98   exponent /= T;                                   98   exponent /= T;
 99                                                    99   
100   if (exponent > 30.0) exponent = 30.0;           100   if (exponent > 30.0) exponent = 30.0;
101                                                   101   
102   _MeanMultiplicity = std::max((FreeVol * theA    102   _MeanMultiplicity = std::max((FreeVol * theA * std::sqrt((G4double)theA)/lambda3) *
103              G4Exp(exponent),1.0e-30);            103              G4Exp(exponent),1.0e-30);
104   return _MeanMultiplicity;                       104   return _MeanMultiplicity; 
105 }                                                 105 }
106                                                   106 
107 G4double G4StatMFMacroMultiNucleon::CalcZARati    107 G4double G4StatMFMacroMultiNucleon::CalcZARatio(const G4double nu)
108 {                                                 108 {
109   G4double den = 8*G4StatMFParameters::GetGamm    109   G4double den = 8*G4StatMFParameters::GetGamma0() 
110     + 2*G4StatMFParameters::GetCoulomb()*G4Pow    110     + 2*G4StatMFParameters::GetCoulomb()*G4Pow::GetInstance()->Z23(theA);
111   theZARatio = (4.0*G4StatMFParameters::GetGam    111   theZARatio = (4.0*G4StatMFParameters::GetGamma0()+nu)/den;
112   return theZARatio;                              112   return theZARatio;
113 }                                                 113 }
114                                                   114 
115 G4double G4StatMFMacroMultiNucleon::CalcEnergy    115 G4double G4StatMFMacroMultiNucleon::CalcEnergy(const G4double T)
116 {                                                 116 {
117   G4Pow* g4calc = G4Pow::GetInstance();           117   G4Pow* g4calc = G4Pow::GetInstance();
118   G4double A23 = g4calc->Z23(theA);               118   G4double A23 = g4calc->Z23(theA);
119                                                   119 
120   // Volume term                                  120   // Volume term 
121   G4double EVol = theA * (T*T/_InvLevelDensity    121   G4double EVol = theA * (T*T/_InvLevelDensity - G4StatMFParameters::GetE0());
122                                                   122   
123   // Symmetry term                                123   // Symmetry term
124   G4double ESym = theA * G4StatMFParameters::G    124   G4double ESym = theA * G4StatMFParameters::GetGamma0() 
125     *(1. - 2.* theZARatio) * (1. - 2.* theZARa    125     *(1. - 2.* theZARatio) * (1. - 2.* theZARatio);
126                                                   126   
127   // Surface term                                 127   // Surface term
128   G4double ESurf = A23*(G4StatMFParameters::Be    128   G4double ESurf = A23*(G4StatMFParameters::Beta(T) - T*G4StatMFParameters::DBetaDT(T));
129                                                   129  
130   // Coulomb term                                 130   // Coulomb term
131   G4double ECoul = G4StatMFParameters::GetCoul    131   G4double ECoul = G4StatMFParameters::GetCoulomb()*A23*theA*theZARatio*theZARatio;
132                                                   132   
133   // Translational term                           133   // Translational term
134   G4double ETrans = 1.5*T;                        134   G4double ETrans = 1.5*T;
135   return _Energy = EVol + ESurf + ECoul + ETra    135   return _Energy = EVol + ESurf + ECoul + ETrans + ESym;
136 }                                                 136 }
137                                                   137 
138 G4double G4StatMFMacroMultiNucleon::CalcEntrop    138 G4double G4StatMFMacroMultiNucleon::CalcEntropy(const G4double T, 
139             const G4double FreeVol)               139             const G4double FreeVol)
140 {                                                 140 {
141   G4double Entropy = 0.0;                         141   G4double Entropy = 0.0;
142   if (_MeanMultiplicity > 0.0) {                  142   if (_MeanMultiplicity > 0.0) {
143                                                   143 
144     G4double ThermalWaveLenght = 16.15*fermi/s    144     G4double ThermalWaveLenght = 16.15*fermi/std::sqrt(T);
145     G4double lambda3 = ThermalWaveLenght*Therm    145     G4double lambda3 = ThermalWaveLenght*ThermalWaveLenght*ThermalWaveLenght;
146     // Volume term                                146     // Volume term
147     G4double SV = 2.0*theA*T/_InvLevelDensity;    147     G4double SV = 2.0*theA*T/_InvLevelDensity;
148                                                   148     
149     // Surface term                               149     // Surface term
150     G4double SS = -G4StatMFParameters::DBetaDT    150     G4double SS = -G4StatMFParameters::DBetaDT(T)*G4Pow::GetInstance()->Z23(theA);
151                                                   151     
152     // Translational term                         152     // Translational term
153     G4double ST = 2.5 + G4Log(FreeVol * std::s    153     G4double ST = 2.5 + G4Log(FreeVol * std::sqrt((G4double)theA) * theA
154             /(lambda3*_MeanMultiplicity));        154             /(lambda3*_MeanMultiplicity));
155                                                   155         
156     Entropy = _MeanMultiplicity*(SV + SS + ST)    156     Entropy = _MeanMultiplicity*(SV + SS + ST);
157   }                                               157   }               
158   return Entropy;                                 158   return Entropy;
159 }                                                 159 }
160                                                   160