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Geant4/processes/hadronic/models/inclxx/utils/include/G4INCLParticleTable.hh

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Differences between /processes/hadronic/models/inclxx/utils/include/G4INCLParticleTable.hh (Version 11.3.0) and /processes/hadronic/models/inclxx/utils/include/G4INCLParticleTable.hh (Version 10.5.p1)


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 25 //                                                 25 //
 26 // INCL++ intra-nuclear cascade model              26 // INCL++ intra-nuclear cascade model
 27 // Alain Boudard, CEA-Saclay, France               27 // Alain Boudard, CEA-Saclay, France
 28 // Joseph Cugnon, University of Liege, Belgium     28 // Joseph Cugnon, University of Liege, Belgium
 29 // Jean-Christophe David, CEA-Saclay, France       29 // Jean-Christophe David, CEA-Saclay, France
 30 // Pekka Kaitaniemi, CEA-Saclay, France, and H     30 // Pekka Kaitaniemi, CEA-Saclay, France, and Helsinki Institute of Physics, Finland
 31 // Sylvie Leray, CEA-Saclay, France                31 // Sylvie Leray, CEA-Saclay, France
 32 // Davide Mancusi, CEA-Saclay, France              32 // Davide Mancusi, CEA-Saclay, France
 33 //                                                 33 //
 34 #define INCLXX_IN_GEANT4_MODE 1                    34 #define INCLXX_IN_GEANT4_MODE 1
 35                                                    35 
 36 #include "globals.hh"                              36 #include "globals.hh"
 37                                                    37 
 38 #ifndef G4INCLParticleTable_hh                     38 #ifndef G4INCLParticleTable_hh
 39 #define G4INCLParticleTable_hh 1                   39 #define G4INCLParticleTable_hh 1
 40                                                    40 
 41 #include <string>                                  41 #include <string>
 42 #include <vector>                                  42 #include <vector>
 43 // #include <cassert>                              43 // #include <cassert>
 44                                                    44 
 45 #include "G4INCLParticleType.hh"                   45 #include "G4INCLParticleType.hh"
 46 #include "G4INCLParticleSpecies.hh"                46 #include "G4INCLParticleSpecies.hh"
 47 #include "G4INCLLogger.hh"                         47 #include "G4INCLLogger.hh"
 48 #include "G4INCLConfig.hh"                         48 #include "G4INCLConfig.hh"
 49 #include "G4INCLHFB.hh"                            49 #include "G4INCLHFB.hh"
 50                                                    50 
 51 #ifdef INCLXX_IN_GEANT4_MODE                       51 #ifdef INCLXX_IN_GEANT4_MODE
 52 #include "G4IonTable.hh"                           52 #include "G4IonTable.hh"
 53 #include "G4ParticleTable.hh"                      53 #include "G4ParticleTable.hh"
 54 #endif                                             54 #endif
 55 #include "G4INCLGlobals.hh"                        55 #include "G4INCLGlobals.hh"
 56 #include "G4INCLNaturalIsotopicDistributions.h     56 #include "G4INCLNaturalIsotopicDistributions.hh"
 57                                                    57 
 58 namespace G4INCL {                                 58 namespace G4INCL {
 59                                                    59 
 60   namespace ParticleTable {                        60   namespace ParticleTable {
 61                                                    61 
 62     const G4int maxClusterMass = 12;               62     const G4int maxClusterMass = 12;
 63     const G4int maxClusterCharge = 8;              63     const G4int maxClusterCharge = 8;
 64                                                    64 
 65     const G4int clusterTableZSize = maxCluster     65     const G4int clusterTableZSize = maxClusterCharge+1;
 66     const G4int clusterTableASize = maxCluster     66     const G4int clusterTableASize = maxClusterMass+1;
 67     const G4int clusterTableSSize = 4;             67     const G4int clusterTableSSize = 4;
 68                                                    68 
 69     const G4double effectiveNucleonMass = 938.     69     const G4double effectiveNucleonMass = 938.2796;
 70     const G4double effectiveNucleonMass2 = 8.8     70     const G4double effectiveNucleonMass2 = 8.8036860777616e5;
 71     const G4double effectiveDeltaMass = 1232.0     71     const G4double effectiveDeltaMass = 1232.0;
 72     const G4double effectiveDeltaWidth = 130.0     72     const G4double effectiveDeltaWidth = 130.0;
 73     const G4double effectivePionMass = 138.0;      73     const G4double effectivePionMass = 138.0;
 74     const G4double effectiveLambdaMass = 1115.     74     const G4double effectiveLambdaMass = 1115.683;
 75     const G4double effectiveSigmaMass = 1197.4     75     const G4double effectiveSigmaMass = 1197.45; // max value
 76     const G4double effectiveXiMass = 1321.71;  << 
 77     const G4double effectiveKaonMass = 497.614     76     const G4double effectiveKaonMass = 497.614; // max value
 78     const G4double effectiveAntiKaonMass = 497     77     const G4double effectiveAntiKaonMass = 497.614; // max value
 79     const G4double effectiveEtaMass = 547.862;     78     const G4double effectiveEtaMass = 547.862;
 80     const G4double effectiveOmegaMass = 782.65     79     const G4double effectiveOmegaMass = 782.65;
 81     const G4double effectiveEtaPrimeMass = 957     80     const G4double effectiveEtaPrimeMass = 957.78;
 82     const G4double effectivePhotonMass = 0.0;      81     const G4double effectivePhotonMass = 0.0;
 83     extern G4ThreadLocal G4double minDeltaMass     82     extern G4ThreadLocal G4double minDeltaMass;
 84     extern G4ThreadLocal G4double minDeltaMass     83     extern G4ThreadLocal G4double minDeltaMass2;
 85     extern G4ThreadLocal G4double minDeltaMass     84     extern G4ThreadLocal G4double minDeltaMassRndm;
 86                                                    85 
 87     /// \brief Initialize the particle table       86     /// \brief Initialize the particle table
 88     void initialize(Config const * const theCo     87     void initialize(Config const * const theConfig = 0);
 89                                                    88 
 90     /// \brief Get the isospin of a particle       89     /// \brief Get the isospin of a particle
 91     G4int getIsospin(const ParticleType t);        90     G4int getIsospin(const ParticleType t);
 92                                                    91 
 93     /// \brief Get the native INCL name of the     92     /// \brief Get the native INCL name of the particle
 94     std::string getName(const ParticleType t);     93     std::string getName(const ParticleType t);
 95                                                    94 
 96     /// \brief Get the short INCL name of the      95     /// \brief Get the short INCL name of the particle
 97     std::string getShortName(const ParticleTyp     96     std::string getShortName(const ParticleType t);
 98                                                    97 
 99     /// \brief Get the native INCL name of the     98     /// \brief Get the native INCL name of the particle
100     std::string getName(const ParticleSpecies      99     std::string getName(const ParticleSpecies &s);
101                                                   100 
102     /// \brief Get the short INCL name of the     101     /// \brief Get the short INCL name of the particle
103     std::string getShortName(const ParticleSpe    102     std::string getShortName(const ParticleSpecies &s);
104                                                   103 
105     /// \brief Get the native INCL name of the    104     /// \brief Get the native INCL name of the ion
106     std::string getName(const G4int A, const G    105     std::string getName(const G4int A, const G4int Z);
107                                                   106 
108     /// \brief Get the native INCL name of the << 
109     std::string getName(const G4int A, const G << 
110                                                << 
111     /// \brief Get the short INCL name of the     107     /// \brief Get the short INCL name of the ion
112     std::string getShortName(const G4int A, co    108     std::string getShortName(const G4int A, const G4int Z);
113                                                   109 
114     /// \brief Get INCL nuclear mass (in MeV/c    110     /// \brief Get INCL nuclear mass (in MeV/c^2)
115     G4double getINCLMass(const G4int A, const     111     G4double getINCLMass(const G4int A, const G4int Z, const G4int S);
116                                                   112 
117     /// \brief Get INCL particle mass (in MeV/    113     /// \brief Get INCL particle mass (in MeV/c^2)
118     G4double getINCLMass(const ParticleType t)    114     G4double getINCLMass(const ParticleType t);
119                                                   115 
120 #ifndef INCLXX_IN_GEANT4_MODE                     116 #ifndef INCLXX_IN_GEANT4_MODE
121     /// \brief Do we have this particle mass?     117     /// \brief Do we have this particle mass?
122     G4double hasMassTable(const unsigned int A    118     G4double hasMassTable(const unsigned int A, const unsigned int Z);
123                                                   119 
124     /** \brief Weizsaecker mass formula           120     /** \brief Weizsaecker mass formula
125      *                                            121      *
126      * Return the nuclear mass, as calculated     122      * Return the nuclear mass, as calculated from Weizsaecker's mass formula.
127      * Adapted from the Geant4 source.            123      * Adapted from the Geant4 source.
128      *                                            124      *
129      * \param A the mass number                   125      * \param A the mass number
130      * \param Z the charge number                 126      * \param Z the charge number
131      * \return the nuclear mass [MeV/c^2]         127      * \return the nuclear mass [MeV/c^2]
132      */                                           128      */
133     G4double getWeizsaeckerMass(const G4int A,    129     G4double getWeizsaeckerMass(const G4int A, const G4int Z);
134 #endif                                            130 #endif
135                                                   131 
136     ///\brief Get particle mass (in MeV/c^2)      132     ///\brief Get particle mass (in MeV/c^2)
137     G4double getRealMass(const G4INCL::Particl    133     G4double getRealMass(const G4INCL::ParticleType t);
138     ///\brief Get nuclear mass (in MeV/c^2)       134     ///\brief Get nuclear mass (in MeV/c^2)
139     G4double getRealMass(const G4int A, const     135     G4double getRealMass(const G4int A, const G4int Z, const G4int S = 0);
140                                                   136 
141     /**\brief Get Q-value (in MeV/c^2)            137     /**\brief Get Q-value (in MeV/c^2)
142      *                                            138      *
143      * Uses the getTableMass function to compu    139      * Uses the getTableMass function to compute the Q-value for the
144      * following reaction:                        140      * following reaction:
145      * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_1+A_2    141      * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_1+A_2,Z_1+Z_2) \f]
146      */                                           142      */
147     G4double getTableQValue(const G4int A1, co    143     G4double getTableQValue(const G4int A1, const G4int Z1, const G4int S1, const G4int A2, const G4int Z2, const G4int S2);
148                                                   144 
149     /**\brief Get Q-value (in MeV/c^2)            145     /**\brief Get Q-value (in MeV/c^2)
150      *                                            146      *
151      * Uses the getTableMass function to compu    147      * Uses the getTableMass function to compute the Q-value for the
152      * following reaction:                        148      * following reaction:
153      * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_3,Z_3    149      * \f[ (A_1,Z_1) + (A_2, Z_2) --> (A_3,Z_3) + (A1+A2-A3,Z1+Z2-Z3) \f]
154      */                                           150      */
155     G4double getTableQValue(const G4int A1, co    151     G4double getTableQValue(const G4int A1, const G4int Z1, const G4int S1, const G4int A2, const G4int Z2, const G4int S2, const G4int A3, const G4int Z3, const G4int S3);
156                                                   152 
157     G4double getTableSpeciesMass(const Particl    153     G4double getTableSpeciesMass(const ParticleSpecies &p);
158                                                   154 
159     /// \brief Get mass number from particle t    155     /// \brief Get mass number from particle type
160     G4int getMassNumber(const ParticleType t);    156     G4int getMassNumber(const ParticleType t);
161                                                   157 
162     /// \brief Get charge number from particle    158     /// \brief Get charge number from particle type
163     G4int getChargeNumber(const ParticleType t    159     G4int getChargeNumber(const ParticleType t);
164                                                   160     
165     /// \brief Get strangeness number from par    161     /// \brief Get strangeness number from particle type
166     G4int getStrangenessNumber(const ParticleT    162     G4int getStrangenessNumber(const ParticleType t);
167                                                   163 
168     G4double getNuclearRadius(const ParticleTy    164     G4double getNuclearRadius(const ParticleType t, const G4int A, const G4int Z);
169     G4double getLargestNuclearRadius(const G4i    165     G4double getLargestNuclearRadius(const G4int A, const G4int Z);
170     G4double getRadiusParameter(const Particle    166     G4double getRadiusParameter(const ParticleType t, const G4int A, const G4int Z);
171     G4double getMaximumNuclearRadius(const Par    167     G4double getMaximumNuclearRadius(const ParticleType t, const G4int A, const G4int Z);
172     G4double getSurfaceDiffuseness(const Parti    168     G4double getSurfaceDiffuseness(const ParticleType t, const G4int A, const G4int Z);
173                                                   169 
174     /// \brief Return the RMS of the momentum     170     /// \brief Return the RMS of the momentum distribution (light clusters)
175     G4double getMomentumRMS(const G4int A, con    171     G4double getMomentumRMS(const G4int A, const G4int Z);
176                                                   172 
177     /// \brief Return INCL's default separatio    173     /// \brief Return INCL's default separation energy
178     G4double getSeparationEnergyINCL(const Par    174     G4double getSeparationEnergyINCL(const ParticleType t, const G4int /*A*/, const G4int /*Z*/);
179                                                   175 
180     /// \brief Return the real separation ener    176     /// \brief Return the real separation energy
181     G4double getSeparationEnergyReal(const Par    177     G4double getSeparationEnergyReal(const ParticleType t, const G4int A, const G4int Z);
182                                                   178 
183     /// \brief Return the real separation ener    179     /// \brief Return the real separation energy only for light nuclei
184     G4double getSeparationEnergyRealForLight(c    180     G4double getSeparationEnergyRealForLight(const ParticleType t, const G4int A, const G4int Z);
185                                                   181 
186     /// \brief Getter for protonSeparationEner    182     /// \brief Getter for protonSeparationEnergy
187     G4double getProtonSeparationEnergy();         183     G4double getProtonSeparationEnergy();
188                                                   184 
189     /// \brief Getter for neutronSeparationEne    185     /// \brief Getter for neutronSeparationEnergy
190     G4double getNeutronSeparationEnergy();        186     G4double getNeutronSeparationEnergy();
191                                                   187 
192     /// \brief Setter for protonSeparationEner    188     /// \brief Setter for protonSeparationEnergy
193     void setProtonSeparationEnergy(const G4dou    189     void setProtonSeparationEnergy(const G4double s);
194                                                   190 
195     /// \brief Setter for protonSeparationEner    191     /// \brief Setter for protonSeparationEnergy
196     void setNeutronSeparationEnergy(const G4do    192     void setNeutronSeparationEnergy(const G4double s);
197                                                   193 
198     /// \brief Get the name of the element fro    194     /// \brief Get the name of the element from the atomic number
199     std::string getElementName(const G4int Z);    195     std::string getElementName(const G4int Z);
200                                                   196 
201     /// \brief Get the name of an unnamed elem    197     /// \brief Get the name of an unnamed element from the IUPAC convention
202     std::string getIUPACElementName(const G4in    198     std::string getIUPACElementName(const G4int Z);
203                                                   199 
204     /// \brief Get the name of the element fro    200     /// \brief Get the name of the element from the atomic number
205     G4int parseElement(std::string pS);           201     G4int parseElement(std::string pS);
206                                                   202 
207     /** \brief Parse a IUPAC element name         203     /** \brief Parse a IUPAC element name
208      *                                            204      *
209      * Note: this function is UGLY. Look at it    205      * Note: this function is UGLY. Look at it at your own peril.
210      *                                            206      *
211      * \param pS a normalised string (lowercas    207      * \param pS a normalised string (lowercase)
212      * \return the charge number of the nuclid    208      * \return the charge number of the nuclide, or zero on fail
213      */                                           209      */
214     G4int parseIUPACElement(std::string const     210     G4int parseIUPACElement(std::string const &pS);
215                                                   211 
216     IsotopicDistribution const &getNaturalIsot    212     IsotopicDistribution const &getNaturalIsotopicDistribution(const G4int Z);
217                                                   213 
218     G4int drawRandomNaturalIsotope(const G4int    214     G4int drawRandomNaturalIsotope(const G4int Z);
219                                                   215 
220     // Typedefs and pointers for transparent h    216     // Typedefs and pointers for transparent handling of mass functions
221     //typedef G4double (*NuclearMassFn)(const     217     //typedef G4double (*NuclearMassFn)(const G4int, const G4int);
222     typedef G4double (*NuclearMassFn)(const G4    218     typedef G4double (*NuclearMassFn)(const G4int, const G4int, const G4int);
223     typedef G4double (*ParticleMassFn)(const P    219     typedef G4double (*ParticleMassFn)(const ParticleType);
224     /// \brief Static pointer to the mass func    220     /// \brief Static pointer to the mass function for nuclei
225     extern G4ThreadLocal NuclearMassFn getTabl    221     extern G4ThreadLocal NuclearMassFn getTableMass;
226     /// \brief Static pointer to the mass func    222     /// \brief Static pointer to the mass function for particles
227     extern G4ThreadLocal ParticleMassFn getTab    223     extern G4ThreadLocal ParticleMassFn getTableParticleMass;
228                                                   224 
229     // Typedefs and pointers for transparent h    225     // Typedefs and pointers for transparent handling of separation energies
230     typedef G4double (*SeparationEnergyFn)(con    226     typedef G4double (*SeparationEnergyFn)(const ParticleType, const G4int, const G4int);
231     /// \brief Static pointer to the separatio    227     /// \brief Static pointer to the separation-energy function
232     extern G4ThreadLocal SeparationEnergyFn ge    228     extern G4ThreadLocal SeparationEnergyFn getSeparationEnergy;
233                                                   229 
234     // Typedefs and pointers for transparent h    230     // Typedefs and pointers for transparent handling of Fermi momentum
235     typedef G4double (*FermiMomentumFn)(const     231     typedef G4double (*FermiMomentumFn)(const G4int, const G4int);
236     extern G4ThreadLocal FermiMomentumFn getFe    232     extern G4ThreadLocal FermiMomentumFn getFermiMomentum;
237                                                   233 
238     /// \brief Return the constant value of th    234     /// \brief Return the constant value of the Fermi momentum
239     G4double getFermiMomentumConstant(const G4    235     G4double getFermiMomentumConstant(const G4int /*A*/, const G4int /*Z*/);
240                                                   236 
241     /** \brief Return the constant value of th    237     /** \brief Return the constant value of the Fermi momentum - special for light
242      *                                            238      *
243      * This function should always return Phys    239      * This function should always return PhysicalConstants::Pf for heavy
244      * nuclei, and values from the momentumRMS    240      * nuclei, and values from the momentumRMS table for light nuclei.
245      *                                            241      *
246      * \param A mass number                       242      * \param A mass number
247      * \param Z charge number                     243      * \param Z charge number
248      */                                           244      */
249     G4double getFermiMomentumConstantLight(con    245     G4double getFermiMomentumConstantLight(const G4int A, const G4int Z);
250                                                   246 
251     /** \brief Return the value Fermi momentum    247     /** \brief Return the value Fermi momentum from a fit
252      *                                            248      *
253      * This function returns a fitted Fermi mo    249      * This function returns a fitted Fermi momentum, based on data from Moniz
254      * et al., Phys. Rev. Lett. 26 (1971) 445.    250      * et al., Phys. Rev. Lett. 26 (1971) 445. The fitted functional form is
255      * \f[                                        251      * \f[
256      * p_F(A)=\alpha-\beta\cdot e^{(-A\cdot\ga    252      * p_F(A)=\alpha-\beta\cdot e^{(-A\cdot\gamma)}
257      * \f]                                        253      * \f]
258      * with \f$\alpha=259.416\f$ MeV/\f$c\f$,     254      * with \f$\alpha=259.416\f$ MeV/\f$c\f$, \f$\beta=152.824\f$ MeV/\f$c\f$
259      * and \f$\gamma=9.5157\cdot10^{-2}\f$.       255      * and \f$\gamma=9.5157\cdot10^{-2}\f$.
260      *                                            256      *
261      * \param A mass number                       257      * \param A mass number
262      */                                           258      */
263     G4double getFermiMomentumMassDependent(con    259     G4double getFermiMomentumMassDependent(const G4int A, const G4int /*Z*/);
264                                                   260 
265     /** \brief Get the value of the r-p correl    261     /** \brief Get the value of the r-p correlation coefficient
266      *                                            262      *
267      * \param t the type of the particle (Prot    263      * \param t the type of the particle (Proton or Neutron)
268      * \return the value of the r-p correlatio    264      * \return the value of the r-p correlation coefficient
269      */                                           265      */
270     G4double getRPCorrelationCoefficient(const    266     G4double getRPCorrelationCoefficient(const ParticleType t);
271                                                   267 
272     /// \brief Get the thickness of the neutro    268     /// \brief Get the thickness of the neutron skin
273     G4double getNeutronSkin();                    269     G4double getNeutronSkin();
274                                                   270 
275     /// \brief Get the size of the neutron hal    271     /// \brief Get the size of the neutron halo
276     G4double getNeutronHalo();                    272     G4double getNeutronHalo();
277                                                   273 
278     /// \brief Get the type of pion               274     /// \brief Get the type of pion
279     ParticleType getPionType(const G4int isosp    275     ParticleType getPionType(const G4int isosp);
280                                                   276 
281     /// \brief Get the type of nucleon            277     /// \brief Get the type of nucleon
282     ParticleType getNucleonType(const G4int is    278     ParticleType getNucleonType(const G4int isosp);
283                                                   279 
284     /// \brief Get the type of delta              280     /// \brief Get the type of delta
285     ParticleType getDeltaType(const G4int isos    281     ParticleType getDeltaType(const G4int isosp);
286                                                   282 
287     /// \brief Get the type of sigma              283     /// \brief Get the type of sigma
288     ParticleType getSigmaType(const G4int isos    284     ParticleType getSigmaType(const G4int isosp);
289                                                << 285 
290     /// \brief Get the type of kaon               286     /// \brief Get the type of kaon
291     ParticleType getKaonType(const G4int isosp    287     ParticleType getKaonType(const G4int isosp);
292                                                   288 
293     /// \brief Get the type of antikaon           289     /// \brief Get the type of antikaon
294     ParticleType getAntiKaonType(const G4int i    290     ParticleType getAntiKaonType(const G4int isosp);
295                                                << 
296     /// \brief Get the type of xi              << 
297     ParticleType getXiType(const G4int isosp); << 
298                                                << 
299     /// \brief Get the type of antinucleon     << 
300     ParticleType getAntiNucleonType(const G4in << 
301                                                << 
302     /// \brief Get the type of antidelta       << 
303     ParticleType getAntiXiType(const G4int iso << 
304                                                << 
305     /// \brief Get the type of antisigma       << 
306     ParticleType getAntiSigmaType(const G4int  << 
307                                                   291 
308     /// \brief Get particle width (in s)          292     /// \brief Get particle width (in s)
309     G4double getWidth(const ParticleType t);      293     G4double getWidth(const ParticleType t);
310   }                                               294   }
311 }                                                 295 }
312                                                   296 
313 #endif                                            297 #endif
314                                                   298 
315                                                   299