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Geant4/processes/hadronic/models/inclxx/incl_physics/src/G4INCLCrossSectionsMultiPionsAndResonances.cc

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Differences between /processes/hadronic/models/inclxx/incl_physics/src/G4INCLCrossSectionsMultiPionsAndResonances.cc (Version 11.3.0) and /processes/hadronic/models/inclxx/incl_physics/src/G4INCLCrossSectionsMultiPionsAndResonances.cc (Version 11.0.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 /** \file G4INCLCrossSectionsMultiPionsAndReso     38 /** \file G4INCLCrossSectionsMultiPionsAndResonances.cc
 39  * \brief Multipion and mesonic Resonances cro     39  * \brief Multipion and mesonic Resonances cross sections
 40  *                                                 40  *
 41  * \date 4th February 2014                         41  * \date 4th February 2014
 42  * \author Jean-Christophe David                   42  * \author Jean-Christophe David
 43  */                                                43  */
 44                                                    44 
 45 #include "G4INCLCrossSectionsMultiPionsAndReso     45 #include "G4INCLCrossSectionsMultiPionsAndResonances.hh"
 46 #include "G4INCLKinematicsUtils.hh"                46 #include "G4INCLKinematicsUtils.hh"
 47 #include "G4INCLParticleTable.hh"                  47 #include "G4INCLParticleTable.hh"
 48 // #include <cassert>                              48 // #include <cassert>
 49                                                    49 
 50 namespace G4INCL {                                 50 namespace G4INCL {
 51                                                    51     
 52     template<G4int N>                              52     template<G4int N>
 53     struct BystrickyEvaluator {                    53     struct BystrickyEvaluator {
 54         static G4double eval(const G4double pL     54         static G4double eval(const G4double pLab, const G4double oneOverThreshold, HornerCoefficients<N> const &coeffs) {
 55             const G4double pMeV = pLab*1E3;        55             const G4double pMeV = pLab*1E3;
 56             const G4double ekin=std::sqrt(Part     56             const G4double ekin=std::sqrt(ParticleTable::effectiveNucleonMass2+pMeV*pMeV)-ParticleTable::effectiveNucleonMass;
 57             const G4double xrat=ekin*oneOverTh     57             const G4double xrat=ekin*oneOverThreshold;
 58             const G4double x=std::log(xrat);       58             const G4double x=std::log(xrat);
 59             return HornerEvaluator<N>::eval(x,     59             return HornerEvaluator<N>::eval(x, coeffs) * x * std::exp(-0.5*x);
 60         }                                          60         }
 61     };                                             61     };
 62                                                    62     
 63     const G4int CrossSectionsMultiPionsAndReso     63     const G4int CrossSectionsMultiPionsAndResonances::nMaxPiNN = 4;
 64     const G4int CrossSectionsMultiPionsAndReso     64     const G4int CrossSectionsMultiPionsAndResonances::nMaxPiPiN = 4;
 65                                                    65     
 66     const G4double CrossSectionsMultiPionsAndR     66     const G4double CrossSectionsMultiPionsAndResonances::s11pzOOT = 0.0035761542037692665889;
 67     const G4double CrossSectionsMultiPionsAndR     67     const G4double CrossSectionsMultiPionsAndResonances::s01ppOOT = 0.003421025623481919853;
 68     const G4double CrossSectionsMultiPionsAndR     68     const G4double CrossSectionsMultiPionsAndResonances::s01pzOOT = 0.0035739814152966403123;
 69     const G4double CrossSectionsMultiPionsAndR     69     const G4double CrossSectionsMultiPionsAndResonances::s11pmOOT = 0.0034855350296270480281;
 70     const G4double CrossSectionsMultiPionsAndR     70     const G4double CrossSectionsMultiPionsAndResonances::s12pmOOT = 0.0016672224074691565119;
 71     const G4double CrossSectionsMultiPionsAndR     71     const G4double CrossSectionsMultiPionsAndResonances::s12ppOOT = 0.0016507643038726931312;
 72     const G4double CrossSectionsMultiPionsAndR     72     const G4double CrossSectionsMultiPionsAndResonances::s12zzOOT = 0.0011111111111111111111;
 73     const G4double CrossSectionsMultiPionsAndR     73     const G4double CrossSectionsMultiPionsAndResonances::s02pzOOT = 0.00125;
 74     const G4double CrossSectionsMultiPionsAndR     74     const G4double CrossSectionsMultiPionsAndResonances::s02pmOOT = 0.0016661112962345883443;
 75     const G4double CrossSectionsMultiPionsAndR     75     const G4double CrossSectionsMultiPionsAndResonances::s12mzOOT = 0.0017047391749062392793;
 76                                                    76     
 77     CrossSectionsMultiPionsAndResonances::Cros     77     CrossSectionsMultiPionsAndResonances::CrossSectionsMultiPionsAndResonances() :
 78     s11pzHC(-2.228000000000294018,8.7560000000     78     s11pzHC(-2.228000000000294018,8.7560000000005723725,-0.61000000000023239325,-5.4139999999999780324,3.3338333333333348023,-0.75835000000000022049,0.060623611111111114688),
 79     s01ppHC(2.0570000000126518344,-6.029000000     79     s01ppHC(2.0570000000126518344,-6.029000000012135826,36.768500000002462784,-45.275666666666553533,25.112666666666611953,-7.2174166666666639187,1.0478875000000000275,-0.060804365079365080846),
 80     s01pzHC(0.18030000000000441851,7.870099999     80     s01pzHC(0.18030000000000441851,7.8700999999999953598,-4.0548999999999990425,0.555199999999999959),
 81     s11pmHC(0.20590000000000031866,3.345099999     81     s11pmHC(0.20590000000000031866,3.3450999999999993936,-1.4401999999999997825,0.17076666666666664973),
 82     s12pmHC(-0.77235999999999901328,4.26265999     82     s12pmHC(-0.77235999999999901328,4.2626599999999991117,-1.9008899999999997323,0.30192266666666663379,-0.012270833333333331986),
 83     s12ppHC(-0.75724999999999975664,2.09343999     83     s12ppHC(-0.75724999999999975664,2.0934399999999998565,-0.3803099999999999814),
 84     s12zzHC(-0.89599999999996965072,7.88299999     84     s12zzHC(-0.89599999999996965072,7.882999999999978632,-7.1049999999999961928,1.884333333333333089),
 85     s02pzHC(-1.0579999999999967036,11.11399999     85     s02pzHC(-1.0579999999999967036,11.113999999999994089,-8.5259999999999990196,2.0051666666666666525),
 86     s02pmHC(2.4009000000012553286,-7.768000000     86     s02pmHC(2.4009000000012553286,-7.7680000000013376183,20.619000000000433505,-16.429666666666723928,5.2525708333333363472,-0.58969166666666670206),
 87     s12mzHC(-0.21858699999999976269,1.91489999     87     s12mzHC(-0.21858699999999976269,1.9148999999999999722,-0.31727500000000001065,-0.027695000000000000486)
 88     {                                              88     {
 89     }                                              89     }
 90                                                    90     
 91     G4double CrossSectionsMultiPionsAndResonan     91     G4double CrossSectionsMultiPionsAndResonances::total(Particle const * const p1, Particle const * const p2) {
 92         G4double inelastic;                        92         G4double inelastic;
 93         if(p1->isNucleon() && p2->isNucleon())     93         if(p1->isNucleon() && p2->isNucleon()) {
 94             return CrossSectionsMultiPions::NN     94             return CrossSectionsMultiPions::NNTot(p1, p2);
 95         } else if((p1->isNucleon() && p2->isDe     95         } else if((p1->isNucleon() && p2->isDelta()) ||
 96                   (p1->isDelta() && p2->isNucl     96                   (p1->isDelta() && p2->isNucleon())) {
 97             inelastic = CrossSectionsMultiPion     97             inelastic = CrossSectionsMultiPions::NDeltaToNN(p1, p2);
 98         } else if((p1->isNucleon() && p2->isPi     98         } else if((p1->isNucleon() && p2->isPion()) ||
 99                   (p1->isPion() && p2->isNucle     99                   (p1->isPion() && p2->isNucleon())) {
100             return CrossSectionsMultiPions::pi    100             return CrossSectionsMultiPions::piNTot(p1,p2);
101         } else if((p1->isNucleon() && p2->isEt    101         } else if((p1->isNucleon() && p2->isEta()) ||
102                   (p1->isEta() && p2->isNucleo    102                   (p1->isEta() && p2->isNucleon())) {
103             inelastic = etaNToPiN(p1,p2) + eta    103             inelastic = etaNToPiN(p1,p2) + etaNToPiPiN(p1,p2);
104         } else if((p1->isNucleon() && p2->isOm    104         } else if((p1->isNucleon() && p2->isOmega()) ||
105                   (p1->isOmega() && p2->isNucl    105                   (p1->isOmega() && p2->isNucleon())) {
106             inelastic = omegaNInelastic(p1,p2)    106             inelastic = omegaNInelastic(p1,p2);
107         } else if((p1->isNucleon() && p2->isEt    107         } else if((p1->isNucleon() && p2->isEtaPrime()) ||
108                   (p1->isEtaPrime() && p2->isN    108                   (p1->isEtaPrime() && p2->isNucleon())) {
109             inelastic = etaPrimeNToPiN(p1,p2);    109             inelastic = etaPrimeNToPiN(p1,p2);
110         } else {                                  110         } else {
111             inelastic = 0.;                       111             inelastic = 0.;
112         }                                         112         }
113                                                   113         
114         return inelastic + elastic(p1, p2);       114         return inelastic + elastic(p1, p2);
115     }                                             115     }    
116                                                   116 
117                                                   117     
118     G4double CrossSectionsMultiPionsAndResonan    118     G4double CrossSectionsMultiPionsAndResonances::elastic(Particle const * const p1, Particle const * const p2) {
119         if((p1->isNucleon()||p1->isDelta()) &&    119         if((p1->isNucleon()||p1->isDelta()) && (p2->isNucleon()||p2->isDelta())){
120             return CrossSectionsMultiPions::el    120             return CrossSectionsMultiPions::elastic(p1, p2);
121         }                                         121         }
122         else if ((p1->isNucleon() && p2->isPio    122         else if ((p1->isNucleon() && p2->isPion()) || (p2->isNucleon() && p1->isPion())){
123             return CrossSectionsMultiPions::el    123             return CrossSectionsMultiPions::elastic(p1, p2);
124         }                                         124         }
125         else if ((p1->isNucleon() && p2->isEta    125         else if ((p1->isNucleon() && p2->isEta()) || (p2->isNucleon() && p1->isEta())){
126             return etaNElastic(p1, p2);           126             return etaNElastic(p1, p2);
127         }                                         127         }
128         else if ((p1->isNucleon() && p2->isOme    128         else if ((p1->isNucleon() && p2->isOmega()) || (p2->isNucleon() && p1->isOmega())){
129             return omegaNElastic(p1, p2);         129             return omegaNElastic(p1, p2);
130         }                                         130         }
131         else {                                    131         else {
132             return 0.0;                           132             return 0.0;
133         }                                         133         }
134     }                                             134     }
135                                                   135     
136                                                   136     
137     G4double CrossSectionsMultiPionsAndResonan    137     G4double CrossSectionsMultiPionsAndResonances::piNToxPiN(const G4int xpi, Particle const * const particle1, Particle const * const particle2) {
138         //                                        138         //
139         //     pion-Nucleon producing xpi pion    139         //     pion-Nucleon producing xpi pions cross sections (corrected due to eta and omega)
140         //                                        140         //
141 // assert(xpi>1 && xpi<=nMaxPiPiN);               141 // assert(xpi>1 && xpi<=nMaxPiPiN);
142 // assert((particle1->isNucleon() && particle2    142 // assert((particle1->isNucleon() && particle2->isPion()) || (particle1->isPion() && particle2->isNucleon()));
143                                                   143 
144         const G4double oldXS2Pi=CrossSectionsM    144         const G4double oldXS2Pi=CrossSectionsMultiPions::piNToxPiN(2,particle1, particle2);
145         const G4double oldXS3Pi=CrossSectionsM    145         const G4double oldXS3Pi=CrossSectionsMultiPions::piNToxPiN(3,particle1, particle2);
146         const G4double oldXS4Pi=CrossSectionsM    146         const G4double oldXS4Pi=CrossSectionsMultiPions::piNToxPiN(4,particle1, particle2);
147         const G4double xsEta=piNToEtaN(particl    147         const G4double xsEta=piNToEtaN(particle1, particle2);
148         const G4double xsOmega=piNToOmegaN(par    148         const G4double xsOmega=piNToOmegaN(particle1, particle2);
149         G4double newXS2Pi=0.;                     149         G4double newXS2Pi=0.;    
150         G4double newXS3Pi=0.;                     150         G4double newXS3Pi=0.;    
151         G4double newXS4Pi=0.;                     151         G4double newXS4Pi=0.;
152                                                   152         
153         if (xpi == 2) {                           153         if (xpi == 2) {
154             if (oldXS4Pi != 0.)                   154             if (oldXS4Pi != 0.)
155                 newXS2Pi=oldXS2Pi;                155                 newXS2Pi=oldXS2Pi;
156             else if (oldXS3Pi != 0.) {            156             else if (oldXS3Pi != 0.) {
157                 newXS3Pi=oldXS3Pi-xsEta-xsOmeg    157                 newXS3Pi=oldXS3Pi-xsEta-xsOmega;
158                 if (newXS3Pi < 1.e-09)            158                 if (newXS3Pi < 1.e-09)
159                     newXS2Pi=oldXS2Pi-(xsEta+x    159                     newXS2Pi=oldXS2Pi-(xsEta+xsOmega-oldXS3Pi);
160                 else                              160                 else
161                     newXS2Pi=oldXS2Pi;            161                     newXS2Pi=oldXS2Pi;
162             }                                     162             }
163             else {                                163             else { 
164                 newXS2Pi=oldXS2Pi-xsEta-xsOmeg    164                 newXS2Pi=oldXS2Pi-xsEta-xsOmega;
165             if (newXS2Pi < 1.e-09)                165             if (newXS2Pi < 1.e-09)
166                     newXS2Pi=0.;                  166                     newXS2Pi=0.;
167             }                                     167             }
168             return newXS2Pi;                      168             return newXS2Pi;
169         }                                         169         }                                            
170         else if (xpi == 3) {                      170         else if (xpi == 3) {
171             if (oldXS4Pi != 0.) {                 171             if (oldXS4Pi != 0.) {
172                 newXS4Pi=oldXS4Pi-xsEta-xsOmeg    172                 newXS4Pi=oldXS4Pi-xsEta-xsOmega;
173                 if (newXS4Pi < 1.e-09)            173                 if (newXS4Pi < 1.e-09)
174                     newXS3Pi=oldXS3Pi-(xsEta+x    174                     newXS3Pi=oldXS3Pi-(xsEta+xsOmega-oldXS4Pi);
175                 else                              175                 else
176                     newXS3Pi=oldXS3Pi;            176                     newXS3Pi=oldXS3Pi;
177             }                                     177             }
178             else {                                178             else { 
179                 newXS3Pi=oldXS3Pi-xsEta-xsOmeg    179                 newXS3Pi=oldXS3Pi-xsEta-xsOmega;
180                 if (newXS3Pi < 1.e-09)            180                 if (newXS3Pi < 1.e-09)
181                     newXS3Pi=0.;                  181                     newXS3Pi=0.;
182             }                                     182             }
183             return newXS3Pi;                      183             return newXS3Pi;
184         }                                         184         }                                    
185         else if (xpi == 4) {                      185         else if (xpi == 4) {
186             newXS4Pi=oldXS4Pi-xsEta-xsOmega;      186             newXS4Pi=oldXS4Pi-xsEta-xsOmega;
187             if (newXS4Pi < 1.e-09)                187             if (newXS4Pi < 1.e-09)
188                 newXS4Pi=0.;                      188                 newXS4Pi=0.;
189             return newXS4Pi;                      189             return newXS4Pi;
190         }                                         190         }            
191         else // should never reach this point     191         else // should never reach this point
192             return 0.;                            192             return 0.;
193     }                                             193     }
194                                                   194     
195     G4double CrossSectionsMultiPionsAndResonan    195     G4double CrossSectionsMultiPionsAndResonances::piNToEtaN(Particle const * const particle1, Particle const * const particle2) {
196         //                                        196         //
197         //     Pion-Nucleon producing Eta cros    197         //     Pion-Nucleon producing Eta cross sections
198         //                                        198         //
199 // assert((particle1->isNucleon() && particle2    199 // assert((particle1->isNucleon() && particle2->isPion()) || (particle1->isPion() && particle2->isNucleon()));
200                                                   200         
201         G4double sigma;                           201         G4double sigma;
202         sigma=piMinuspToEtaN(particle1,particl    202         sigma=piMinuspToEtaN(particle1,particle2);
203                                                   203         
204         const G4int isoin = ParticleTable::get    204         const G4int isoin = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
205                                                   205         
206         if (isoin == -1) {                        206         if (isoin == -1) {
207             if ((particle1->getType()) == Prot    207             if ((particle1->getType()) == Proton || (particle2->getType()) == Proton) return sigma;
208             else return 0.5 * sigma;              208             else return 0.5 * sigma;
209         }                                         209         }
210         else if (isoin == 1) {                    210         else if (isoin == 1) {
211             if ((particle1->getType()) == Neut    211             if ((particle1->getType()) == Neutron || (particle2->getType()) == Neutron) return sigma;
212             else return 0.5 * sigma;              212             else return 0.5 * sigma;
213         }                                         213         }
214         else return 0. ; // should never retur    214         else return 0. ; // should never return 0. (?) // pi+ p and pi- n return 0.
215                                                   215         
216 //        return sigma;                           216 //        return sigma;
217     }                                             217     }
218                                                   218     
219     G4double CrossSectionsMultiPionsAndResonan    219     G4double CrossSectionsMultiPionsAndResonances::piNToOmegaN(Particle const * const particle1, Particle const * const particle2) {
220         //                                        220         //
221         //     Pion-Nucleon producing Omega cr    221         //     Pion-Nucleon producing Omega cross sections
222         //                                        222         //
223 // assert((particle1->isNucleon() && particle2    223 // assert((particle1->isNucleon() && particle2->isPion()) || (particle1->isPion() && particle2->isNucleon()));
224                                                   224         
225         G4double sigma;                           225         G4double sigma;
226         sigma=piMinuspToOmegaN(particle1,parti    226         sigma=piMinuspToOmegaN(particle1,particle2);
227                                                   227         
228         const G4int isoin = ParticleTable::get    228         const G4int isoin = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
229                                                   229         
230         if (isoin == -1) {                        230         if (isoin == -1) {
231             if ((particle1->getType()) == Prot    231             if ((particle1->getType()) == Proton || (particle2->getType()) == Proton) return sigma;
232             else return 0.5 * sigma;              232             else return 0.5 * sigma;
233         }                                         233         }
234         else if (isoin == 1) {                    234         else if (isoin == 1) {
235             if ((particle1->getType()) == Neut    235             if ((particle1->getType()) == Neutron || (particle2->getType()) == Neutron) return sigma;
236             else return 0.5 * sigma;              236             else return 0.5 * sigma;
237         }                                         237         }
238         else return 0. ; // should never retur    238         else return 0. ; // should never return 0. (?) // pi+ p and pi- n return 0.
239                                                   239         
240 //        return sigma;                           240 //        return sigma;
241     }                                             241     }
242                                                   242     
243 #if defined(NDEBUG) || defined(INCLXX_IN_GEANT    243 #if defined(NDEBUG) || defined(INCLXX_IN_GEANT4_MODE)
244     G4double CrossSectionsMultiPionsAndResonan    244     G4double CrossSectionsMultiPionsAndResonances::piNToEtaPrimeN(Particle const * const /*particle1*/, Particle const * const /*particle2*/) {
245 #else                                             245 #else
246     G4double CrossSectionsMultiPionsAndResonan    246     G4double CrossSectionsMultiPionsAndResonances::piNToEtaPrimeN(Particle const * const particle1, Particle const * const particle2) {
247 #endif                                            247 #endif
248         //                                        248         //
249         //     Pion-Nucleon producing EtaPrime    249         //     Pion-Nucleon producing EtaPrime cross sections
250         //                                        250         //
251 // assert((particle1->isNucleon() && particle2    251 // assert((particle1->isNucleon() && particle2->isPion()) || (particle1->isPion() && particle2->isNucleon()));
252                                                   252         
253         return 0.;                                253         return 0.;
254     }                                             254     }
255                                                   255     
256     G4double CrossSectionsMultiPionsAndResonan    256     G4double CrossSectionsMultiPionsAndResonances::etaNToPiN(Particle const * const particle1, Particle const * const particle2) {
257         //                                        257         //
258         //     Eta-Nucleon producing Pion cros    258         //     Eta-Nucleon producing Pion cross sections
259         //                                        259         //
260 // assert((particle1->isNucleon() && particle2    260 // assert((particle1->isNucleon() && particle2->isEta()) || (particle1->isEta() && particle2->isNucleon()));
261                                                   261         
262         const Particle *eta;                      262         const Particle *eta;
263         const Particle *nucleon;                  263         const Particle *nucleon;
264                                                   264         
265         if (particle1->isEta()) {                 265         if (particle1->isEta()) {
266          eta = particle1;                         266          eta = particle1;
267          nucleon = particle2;                     267          nucleon = particle2;
268         }                                         268         }
269         else {                                    269         else {
270          eta = particle2;                         270          eta = particle2;
271          nucleon = particle1;                     271          nucleon = particle1;
272         }                                         272         }
273                                                   273         
274         const G4double pLab = KinematicsUtils:    274         const G4double pLab = KinematicsUtils::momentumInLab(eta, nucleon);
275         G4double sigma=0.;                        275         G4double sigma=0.;        
276                                                   276         
277         if (pLab <= 574.)                         277         if (pLab <= 574.) 
278          sigma= 1.511147E-13*std::pow(pLab,6)-    278          sigma= 1.511147E-13*std::pow(pLab,6)- 3.603636E-10*std::pow(pLab,5)+ 3.443487E-07*std::pow(pLab,4)- 1.681980E-04*std::pow(pLab,3)+ 4.437913E-02*std::pow(pLab,2)- 6.172108E+00*pLab+ 4.031449E+02;
279         else if (pLab <= 850.)                    279         else if (pLab <= 850.) 
280          sigma= -8.00018E-14*std::pow(pLab,6)+    280          sigma= -8.00018E-14*std::pow(pLab,6)+ 3.50041E-10*std::pow(pLab,5)- 6.33891E-07*std::pow(pLab,4)+ 6.07658E-04*std::pow(pLab,3)- 3.24936E-01*std::pow(pLab,2)+ 9.18098E+01*pLab- 1.06943E+04;
281         else if (pLab <= 1300.)                   281         else if (pLab <= 1300.)
282          sigma= 6.56364E-09*std::pow(pLab,3)-     282          sigma= 6.56364E-09*std::pow(pLab,3)- 2.07653E-05*std::pow(pLab,2)+ 1.84148E-02*pLab- 1.70427E+00;     
283         else {                                    283         else {
284             G4double ECM=KinematicsUtils::tota    284             G4double ECM=KinematicsUtils::totalEnergyInCM(eta, nucleon);
285             G4double massPiZero=ParticleTable:    285             G4double massPiZero=ParticleTable::getINCLMass(PiZero);
286             G4double massPiMinus=ParticleTable    286             G4double massPiMinus=ParticleTable::getINCLMass(PiMinus);
287             G4double massProton=ParticleTable:    287             G4double massProton=ParticleTable::getINCLMass(Proton);
288             G4double masseta;                     288             G4double masseta;
289             G4double massnucleon;                 289             G4double massnucleon;
290             G4double pCM_eta;                     290             G4double pCM_eta;
291             masseta=eta->getMass();               291             masseta=eta->getMass();
292             massnucleon=nucleon->getMass();       292             massnucleon=nucleon->getMass();
293             pCM_eta=KinematicsUtils::momentumI    293             pCM_eta=KinematicsUtils::momentumInCM(ECM, masseta, massnucleon);         
294             G4double pCM_PiZero=KinematicsUtil    294             G4double pCM_PiZero=KinematicsUtils::momentumInCM(ECM, massPiZero, massProton);
295             G4double pCM_PiMinus=KinematicsUti    295             G4double pCM_PiMinus=KinematicsUtils::momentumInCM(ECM, massPiMinus, massProton); // = pCM_PiPlus (because massPiMinus = massPiPlus) 
296             sigma = (piMinuspToEtaN(ECM)/2.) *    296             sigma = (piMinuspToEtaN(ECM)/2.) * std::pow((pCM_PiZero/pCM_eta), 2) + piMinuspToEtaN(ECM) * std::pow((pCM_PiMinus/pCM_eta), 2);            
297         }                                         297         } 
298         if (sigma < 0.) sigma=0.;                 298         if (sigma < 0.) sigma=0.;
299                                                   299         
300         return sigma;                             300         return sigma;
301     }                                             301     }
302                                                   302 
303     G4double CrossSectionsMultiPionsAndResonan    303     G4double CrossSectionsMultiPionsAndResonances::etaNToPiPiN(Particle const * const particle1, Particle const * const particle2) {
304         //                                        304         //
305         //     Eta-Nucleon producing Two Pions    305         //     Eta-Nucleon producing Two Pions cross sections
306         //                                        306         //
307 // assert((particle1->isNucleon() && particle2    307 // assert((particle1->isNucleon() && particle2->isEta()) || (particle1->isEta() && particle2->isNucleon()));
308                                                   308 
309         G4double sigma=0.;                        309         G4double sigma=0.;        
310                                                   310 
311         const Particle *eta;                      311         const Particle *eta;
312         const Particle *nucleon;                  312         const Particle *nucleon;
313                                                   313 
314         if (particle1->isEta()) {                 314         if (particle1->isEta()) {
315             eta = particle1;                      315             eta = particle1;
316             nucleon = particle2;                  316             nucleon = particle2;
317         }                                         317         }
318         else {                                    318         else {
319             eta = particle2;                      319             eta = particle2;
320             nucleon = particle1;                  320             nucleon = particle1;
321         }                                         321         }
322                                                   322 
323         const G4double pLab = KinematicsUtils:    323         const G4double pLab = KinematicsUtils::momentumInLab(eta, nucleon);
324                                                   324         
325         if (pLab < 450.)                          325         if (pLab < 450.) 
326             sigma = 2.01854221E-13*std::pow(pL    326             sigma = 2.01854221E-13*std::pow(pLab,6) - 3.49750459E-10*std::pow(pLab,5) + 2.46011585E-07*std::pow(pLab,4) - 9.01422901E-05*std::pow(pLab,3) + 1.83382964E-02*std::pow(pLab,2) - 2.03113098E+00*pLab + 1.10358550E+02;                
327         else if (pLab < 600.)                     327         else if (pLab < 600.) 
328             sigma = 2.01854221E-13*std::pow(45    328             sigma = 2.01854221E-13*std::pow(450.,6) - 3.49750459E-10*std::pow(450.,5) + 2.46011585E-07*std::pow(450.,4) - 9.01422901E-05*std::pow(450.,3) + 1.83382964E-02*std::pow(450.,2) - 2.03113098E+00*450. + 1.10358550E+02;                
329         else if (pLab <= 1300.)                   329         else if (pLab <= 1300.) 
330             sigma = -6.32793049e-16*std::pow(p    330             sigma = -6.32793049e-16*std::pow(pLab,6) + 3.95985900e-12*std::pow(pLab,5) - 1.01727714e-8*std::pow(pLab,4) + 
331             1.37055547e-05*std::pow(pLab,3) -     331             1.37055547e-05*std::pow(pLab,3) - 1.01830486e-02*std::pow(pLab,2) + 3.93492126*pLab - 609.447145;
332         else                                      332         else 
333             sigma = etaNToPiN(particle1,partic    333             sigma = etaNToPiN(particle1,particle2);
334                                                   334 
335         if (sigma < 0.) sigma = 0.;               335         if (sigma < 0.) sigma = 0.;
336         return sigma; // Parameterization from    336         return sigma; // Parameterization from the ANL-Osaka DCC model [PRC88(2013)035209] - eta p --> "pi+pi0 n" + "pi0 pi0 p" total XS
337     }                                             337     }
338                                                   338         
339                                                   339         
340     G4double CrossSectionsMultiPionsAndResonan    340     G4double CrossSectionsMultiPionsAndResonances::etaNElastic(Particle const * const particle1, Particle const * const particle2) {
341         //                                        341         //
342         //     Eta-Nucleon elastic cross secti    342         //     Eta-Nucleon elastic cross sections
343         //                                        343         //
344 // assert((particle1->isNucleon() && particle2    344 // assert((particle1->isNucleon() && particle2->isEta()) || (particle1->isEta() && particle2->isNucleon()));
345                                                   345         
346         G4double sigma=0.;                        346         G4double sigma=0.;        
347                                                   347         
348         const Particle *eta;                      348         const Particle *eta;
349         const Particle *nucleon;                  349         const Particle *nucleon;
350                                                   350         
351         if (particle1->isEta()) {                 351         if (particle1->isEta()) {
352             eta = particle1;                      352             eta = particle1;
353             nucleon = particle2;                  353             nucleon = particle2;
354         }                                         354         }
355         else {                                    355         else {
356             eta = particle2;                      356             eta = particle2;
357             nucleon = particle1;                  357             nucleon = particle1;
358         }                                         358         }
359                                                   359         
360         const G4double pLab = KinematicsUtils:    360         const G4double pLab = KinematicsUtils::momentumInLab(eta, nucleon);
361                                                   361         
362         if (pLab < 700.)                          362         if (pLab < 700.) 
363             sigma = 3.6838e-15*std::pow(pLab,6    363             sigma = 3.6838e-15*std::pow(pLab,6) - 9.7815e-12*std::pow(pLab,5) + 9.7914e-9*std::pow(pLab,4) - 
364             4.3222e-06*std::pow(pLab,3) + 7.91    364             4.3222e-06*std::pow(pLab,3) + 7.9188e-04*std::pow(pLab,2) - 1.8379e-01*pLab + 84.965;            
365         else if (pLab < 1400.)                    365         else if (pLab < 1400.) 
366             sigma = 3.562630e-16*std::pow(pLab    366             sigma = 3.562630e-16*std::pow(pLab,6) - 2.384766e-12*std::pow(pLab,5) + 6.601312e-9*std::pow(pLab,4) - 
367             9.667078e-06*std::pow(pLab,3) + 7.    367             9.667078e-06*std::pow(pLab,3) + 7.894845e-03*std::pow(pLab,2) - 3.409200*pLab + 609.8501;
368         else if (pLab < 2025.)                    368         else if (pLab < 2025.)
369             sigma = -1.041950E-03*pLab + 2.110    369             sigma = -1.041950E-03*pLab + 2.110529E+00;
370         else                                      370         else    
371             sigma=0.;                             371             sigma=0.;
372                                                   372         
373         if (sigma < 0.) sigma = 0.;               373         if (sigma < 0.) sigma = 0.;
374             return sigma; // Parameterization     374             return sigma; // Parameterization from the ANL-Osaka DCC model [PRC88(2013)035209]
375         }                                         375         }
376                                                   376 
377     G4double CrossSectionsMultiPionsAndResonan    377     G4double CrossSectionsMultiPionsAndResonances::omegaNInelastic(Particle const * const particle1, Particle const * const particle2) {
378         //                                        378         //
379         //     Omega-Nucleon inelastic cross s    379         //     Omega-Nucleon inelastic cross sections
380         //                                        380         //
381 // assert((particle1->isNucleon() && particle2    381 // assert((particle1->isNucleon() && particle2->isOmega()) || (particle1->isOmega() && particle2->isNucleon()));
382                                                   382         
383         G4double sigma=0.;                        383         G4double sigma=0.;        
384                                                   384         
385         const Particle *omega;                    385         const Particle *omega;
386         const Particle *nucleon;                  386         const Particle *nucleon;
387                                                   387         
388         if (particle1->isOmega()) {               388         if (particle1->isOmega()) {
389             omega = particle1;                    389             omega = particle1;
390             nucleon = particle2;                  390             nucleon = particle2;
391             }                                     391             }
392         else {                                    392         else {
393             omega = particle2;                    393             omega = particle2;
394             nucleon = particle1;                  394             nucleon = particle1;
395         }                                         395         }
396                                                   396         
397         const G4double pLab = KinematicsUtils:    397         const G4double pLab = KinematicsUtils::momentumInLab(omega, nucleon)/1000.; // GeV/c
398                                                   398         
399         sigma = 20. + 4.0/pLab;    // Eq.(24)     399         sigma = 20. + 4.0/pLab;    // Eq.(24) in G.I. Lykasov et al., EPJA 6, 71-81 (1999)
400                                                   400         
401         return sigma;                             401         return sigma;
402     }                                             402     }
403                                                   403 
404                                                   404   
405     G4double CrossSectionsMultiPionsAndResonan    405     G4double CrossSectionsMultiPionsAndResonances::omegaNElastic(Particle const * const particle1, Particle const * const particle2) {
406         //                                        406         //
407         //     Omega-Nucleon elastic cross sec    407         //     Omega-Nucleon elastic cross sections
408         //                                        408         //
409 // assert((particle1->isNucleon() && particle2    409 // assert((particle1->isNucleon() && particle2->isOmega()) || (particle1->isOmega() && particle2->isNucleon()));
410                                                   410         
411         G4double sigma=0.;                        411         G4double sigma=0.;        
412                                                   412         
413         const Particle *omega;                    413         const Particle *omega;
414         const Particle *nucleon;                  414         const Particle *nucleon;
415                                                   415         
416         if (particle1->isOmega()) {               416         if (particle1->isOmega()) {
417             omega = particle1;                    417             omega = particle1;
418             nucleon = particle2;                  418             nucleon = particle2;
419         }                                         419         }
420         else {                                    420         else {
421             omega = particle2;                    421             omega = particle2;
422             nucleon = particle1;                  422             nucleon = particle1;
423         }                                         423         }
424                                                   424         
425         const G4double pLab = KinematicsUtils:    425         const G4double pLab = KinematicsUtils::momentumInLab(omega, nucleon)/1000.; // GeV/c
426                                                   426         
427         sigma = 5.4 + 10.*std::exp(-0.6*pLab);    427         sigma = 5.4 + 10.*std::exp(-0.6*pLab);    // Eq.(21) in G.I. Lykasov et al., EPJA 6, 71-81 (1999)
428                                                   428         
429         return sigma;                             429         return sigma;
430     }                                             430     }
431                                                   431   
432                                                   432         
433     G4double CrossSectionsMultiPionsAndResonan    433     G4double CrossSectionsMultiPionsAndResonances::omegaNToPiN(Particle const * const particle1, Particle const * const particle2) {
434         //                                        434         //
435         //     Omega-Nucleon producing Pion cr    435         //     Omega-Nucleon producing Pion cross sections
436         //                                        436         //
437 // assert((particle1->isNucleon() && particle2    437 // assert((particle1->isNucleon() && particle2->isOmega()) || (particle1->isOmega() && particle2->isNucleon()));
438                                                   438         
439         G4double ECM=KinematicsUtils::totalEne    439         G4double ECM=KinematicsUtils::totalEnergyInCM(particle1, particle2);
440                                                   440         
441         G4double massPiZero=ParticleTable::get    441         G4double massPiZero=ParticleTable::getINCLMass(PiZero);
442         G4double massPiMinus=ParticleTable::ge    442         G4double massPiMinus=ParticleTable::getINCLMass(PiMinus);
443         G4double massProton=ParticleTable::get    443         G4double massProton=ParticleTable::getINCLMass(Proton);
444                                                   444         
445         G4double massomega;                       445         G4double massomega;
446         G4double massnucleon;                     446         G4double massnucleon;
447         G4double pCM_omega;                       447         G4double pCM_omega;
448         G4double pLab_omega;                      448         G4double pLab_omega;
449                                                   449         
450         G4double sigma=0.;                        450         G4double sigma=0.;        
451                                                   451         
452         if (particle1->isOmega()) {               452         if (particle1->isOmega()) {
453             massomega=particle1->getMass();       453             massomega=particle1->getMass();
454             massnucleon=particle2->getMass();     454             massnucleon=particle2->getMass();
455         }                                         455         }
456         else {                                    456         else {
457             massomega=particle2->getMass();       457             massomega=particle2->getMass();
458             massnucleon=particle1->getMass();     458             massnucleon=particle1->getMass();
459         }                                         459         }
460         pCM_omega=KinematicsUtils::momentumInC    460         pCM_omega=KinematicsUtils::momentumInCM(ECM, massomega, massnucleon);        
461         pLab_omega=KinematicsUtils::momentumIn    461         pLab_omega=KinematicsUtils::momentumInLab(ECM*ECM, massomega, massnucleon);        
462                                                   462         
463         G4double pCM_PiZero=KinematicsUtils::m    463         G4double pCM_PiZero=KinematicsUtils::momentumInCM(ECM, massPiZero, massProton);
464         G4double pCM_PiMinus=KinematicsUtils::    464         G4double pCM_PiMinus=KinematicsUtils::momentumInCM(ECM, massPiMinus, massProton); // = pCM_PiPlus (because massPiMinus = massPiPlus)
465                                                   465         
466         sigma = (piMinuspToOmegaN(ECM)/2.) * s    466         sigma = (piMinuspToOmegaN(ECM)/2.) * std::pow((pCM_PiZero/pCM_omega), 2) 
467         + piMinuspToOmegaN(ECM) * std::pow((pC    467         + piMinuspToOmegaN(ECM) * std::pow((pCM_PiMinus/pCM_omega), 2);            
468                                                   468   
469         if (sigma > omegaNInelastic(particle1,    469         if (sigma > omegaNInelastic(particle1, particle2) || (pLab_omega < 200.)) {
470 //        if (sigma > omegaNInelastic(particle    470 //        if (sigma > omegaNInelastic(particle1, particle2)) {
471             sigma = omegaNInelastic(particle1,    471             sigma = omegaNInelastic(particle1, particle2);
472         }                                         472         }  
473                                                   473   
474         return sigma;                             474         return sigma;
475     }                                             475     }
476                                                   476     
477                                                   477   
478     G4double CrossSectionsMultiPionsAndResonan    478     G4double CrossSectionsMultiPionsAndResonances::omegaNToPiPiN(Particle const * const particle1, Particle const * const particle2) {
479         //                                        479         //
480         //     Omega-Nucleon producing 2 PionS    480         //     Omega-Nucleon producing 2 PionS cross sections
481         //                                        481         //
482 // assert((particle1->isNucleon() && particle2    482 // assert((particle1->isNucleon() && particle2->isOmega()) || (particle1->isOmega() && particle2->isNucleon()));
483                                                   483         
484         G4double sigma=0.;                        484         G4double sigma=0.;        
485                                                   485         
486         sigma = omegaNInelastic(particle1,part    486         sigma = omegaNInelastic(particle1,particle2) - omegaNToPiN(particle1,particle2) ;
487                                                   487         
488         return sigma;                             488         return sigma;
489     }                                             489     }
490                                                   490   
491                                                   491     
492 #if defined(NDEBUG) || defined(INCLXX_IN_GEANT    492 #if defined(NDEBUG) || defined(INCLXX_IN_GEANT4_MODE)
493   G4double CrossSectionsMultiPionsAndResonance    493   G4double CrossSectionsMultiPionsAndResonances::etaPrimeNToPiN(Particle const * const /*particle1*/, Particle const * const /*particle2*/) {
494 #else                                             494 #else
495   G4double CrossSectionsMultiPionsAndResonance    495   G4double CrossSectionsMultiPionsAndResonances::etaPrimeNToPiN(Particle const * const particle1, Particle const * const particle2) {
496 #endif                                            496 #endif
497         //                                        497         //
498         //     EtaPrime-Nucleon producing Pion    498         //     EtaPrime-Nucleon producing Pion cross sections
499         //                                        499         //
500 // assert((particle1->isNucleon() && particle2    500 // assert((particle1->isNucleon() && particle2->isEtaPrime()) || (particle1->isEtaPrime() && particle2->isNucleon()));
501                                                   501         
502         return 0.;                                502         return 0.;
503     }                                             503     }    
504                                                   504     
505     G4double CrossSectionsMultiPionsAndResonan    505     G4double CrossSectionsMultiPionsAndResonances::piMinuspToEtaN(Particle const * const particle1, Particle const * const particle2) {
506         //                                        506         //
507         //     Pion-Nucleon producing Eta cros    507         //     Pion-Nucleon producing Eta cross sections
508         //                                        508         //
509 // assert((particle1->isNucleon() && particle2    509 // assert((particle1->isNucleon() && particle2->isPion()) || (particle1->isPion() && particle2->isNucleon()));
510                                                   510         
511         G4double masspion;                        511         G4double masspion;
512         G4double massnucleon;                     512         G4double massnucleon;
513         if (particle1->isPion()) {                513         if (particle1->isPion()) {
514             masspion=particle1->getMass();        514             masspion=particle1->getMass();
515             massnucleon=particle2->getMass();     515             massnucleon=particle2->getMass();
516         }                                         516         }
517         else {                                    517         else {
518             masspion=particle2->getMass();        518             masspion=particle2->getMass();
519             massnucleon=particle1->getMass();     519             massnucleon=particle1->getMass();
520         }                                         520         }
521                                                   521         
522         G4double ECM=KinematicsUtils::totalEne    522         G4double ECM=KinematicsUtils::totalEnergyInCM(particle1, particle2);
523         G4double plab=KinematicsUtils::momentu    523         G4double plab=KinematicsUtils::momentumInLab(ECM*ECM, masspion, massnucleon)/1000.; // GeV/c
524                                                   524         
525         G4double sigma;                           525         G4double sigma;
526                                                   526         
527 // new parameterization (JCD) - end of februar    527 // new parameterization (JCD) - end of february 2016
528         if (ECM < 1486.5) sigma=0.;               528         if (ECM < 1486.5) sigma=0.;
529         else                                      529         else
530         {                                         530         {
531             if (ECM < 1535.)                      531             if (ECM < 1535.)
532             {                                     532             {
533                 sigma = -0.0000003689197974814    533                 sigma = -0.0000003689197974814*std::pow(ECM,4) + 0.002260193900097*std::pow(ECM,3) - 5.193105877187*std::pow(ECM,2) + 5303.505273919*ECM - 2031265.900648;
534             }                                     534             }
535             else if (ECM < 1670.)                 535             else if (ECM < 1670.)
536             {                                     536             {
537                 sigma = -0.0000000337986446*st    537                 sigma = -0.0000000337986446*std::pow(ECM,4) + 0.000218279989*std::pow(ECM,3) - 0.528276144*std::pow(ECM,2) + 567.828367*ECM - 228709.42;
538             }                                     538             }
539             else if (ECM < 1714.)                 539             else if (ECM < 1714.)
540             {                                     540             {
541                 sigma =  0.000003737765*std::p    541                 sigma =  0.000003737765*std::pow(ECM,2) - 0.005664062*ECM;
542             }                                     542             }
543             else sigma=1.47*std::pow(plab, -1.    543             else sigma=1.47*std::pow(plab, -1.68);
544         }                                         544         }        
545 //                                                545 //        
546                                                   546 
547         return sigma;                             547         return sigma;
548     }                                             548     }
549                                                   549     
550     G4double CrossSectionsMultiPionsAndResonan    550     G4double CrossSectionsMultiPionsAndResonances::piMinuspToEtaN(const G4double ECM) {
551         //                                        551         //
552         //     Pion-Nucleon producing Eta cros    552         //     Pion-Nucleon producing Eta cross sections
553         //                                        553         //
554                                                   554         
555         const G4double masspion = ParticleTabl    555         const G4double masspion = ParticleTable::getRealMass(PiMinus);        
556         const G4double massnucleon = ParticleT    556         const G4double massnucleon = ParticleTable::getRealMass(Proton);        
557                                                   557   
558         G4double plab=KinematicsUtils::momentu    558         G4double plab=KinematicsUtils::momentumInLab(ECM*ECM, masspion, massnucleon)/1000.;  // GeV/c
559                                                   559         
560         G4double sigma;                           560         G4double sigma;
561                                                   561         
562 // new parameterization (JCD) - end of februar    562 // new parameterization (JCD) - end of february 2016
563         if (ECM < 1486.5) sigma=0.;               563         if (ECM < 1486.5) sigma=0.;
564         else                                      564         else
565         {                                         565         {
566             if (ECM < 1535.)                      566             if (ECM < 1535.)
567             {                                     567             {
568                 sigma = -0.0000003689197974814    568                 sigma = -0.0000003689197974814*std::pow(ECM,4) + 0.002260193900097*std::pow(ECM,3) - 5.193105877187*std::pow(ECM,2) + 5303.505273919*ECM - 2031265.900648;
569             }                                     569             }
570             else if (ECM < 1670.)                 570             else if (ECM < 1670.)
571             {                                     571             {
572                 sigma = -0.0000000337986446*st    572                 sigma = -0.0000000337986446*std::pow(ECM,4) + 0.000218279989*std::pow(ECM,3) - 0.528276144*std::pow(ECM,2) + 567.828367*ECM - 228709.42;
573             }                                     573             }
574             else if (ECM < 1714.)                 574             else if (ECM < 1714.)
575             {                                     575             {
576                 sigma =  0.000003737765*std::p    576                 sigma =  0.000003737765*std::pow(ECM,2) - 0.005664062*ECM;
577             }                                     577             }
578             else sigma=1.47*std::pow(plab, -1.    578             else sigma=1.47*std::pow(plab, -1.68);
579         }                                         579         }
580                                                   580         
581         return sigma;                             581         return sigma;
582     }                                             582     }
583                                                   583 
584     G4double CrossSectionsMultiPionsAndResonan    584     G4double CrossSectionsMultiPionsAndResonances::piMinuspToOmegaN(Particle const * const particle1, Particle const * const particle2) {
585         //                                        585         //
586         //     Pion-Nucleon producing Omega cr    586         //     Pion-Nucleon producing Omega cross sections
587         //                                        587         //
588 // assert((particle1->isNucleon() && particle2    588 // assert((particle1->isNucleon() && particle2->isPion()) || (particle1->isPion() && particle2->isNucleon()));
589 //jcd to be removed                               589 //jcd to be removed
590 //        return 0.;                              590 //        return 0.;
591 //jcd                                             591 //jcd    
592                                                   592         
593 //        G4double param=1.095 ; // Deneye (Th    593 //        G4double param=1.095 ; // Deneye (Thesis)
594         G4double param=1.0903 ; // JCD (thresh    594         G4double param=1.0903 ; // JCD (threshold taken into account)
595                                                   595   
596         G4double masspion;                        596         G4double masspion;
597         G4double massnucleon;                     597         G4double massnucleon;
598         if (particle1->isPion()) {                598         if (particle1->isPion()) {
599             masspion=particle1->getMass();        599             masspion=particle1->getMass();
600             massnucleon=particle2->getMass();     600             massnucleon=particle2->getMass();
601         }                                         601         }
602         else {                                    602         else {
603             masspion=particle2->getMass();        603             masspion=particle2->getMass();
604             massnucleon=particle1->getMass();     604             massnucleon=particle1->getMass();
605         }                                         605         }
606         G4double ECM=KinematicsUtils::totalEne    606         G4double ECM=KinematicsUtils::totalEnergyInCM(particle1, particle2);
607         G4double plab=KinematicsUtils::momentu    607         G4double plab=KinematicsUtils::momentumInLab(ECM*ECM, masspion, massnucleon)/1000.;  // GeV/c
608                                                   608         
609         G4double sigma;                           609         G4double sigma;
610         if (plab < param) sigma=0.;               610         if (plab < param) sigma=0.;
611         else sigma=13.76*(plab-param)/(std::po    611         else sigma=13.76*(plab-param)/(std::pow(plab, 3.33) - 1.07); // Phys. Rev. C 41, 1701–1718 (1990)
612                                                   612   
613         return sigma;                             613         return sigma;
614 }                                                 614 }
615     G4double CrossSectionsMultiPionsAndResonan    615     G4double CrossSectionsMultiPionsAndResonances::piMinuspToOmegaN(const G4double ECM) {
616         //                                        616         //
617         //     Pion-Nucleon producing Omega cr    617         //     Pion-Nucleon producing Omega cross sections
618         //                                        618         //
619 //jcd to be removed                               619 //jcd to be removed
620 //    return 0.;                                  620 //    return 0.;
621 //jcd                                             621 //jcd    
622                                                   622                 
623 //        G4double param=1.095 ; // Deneye (Th    623 //        G4double param=1.095 ; // Deneye (Thesis)
624         G4double param=1.0903 ; // JCD (thresh    624         G4double param=1.0903 ; // JCD (threshold taken into account)
625                                                   625 
626         const G4double masspion = ParticleTabl    626         const G4double masspion = ParticleTable::getRealMass(PiMinus);        
627         const G4double massnucleon = ParticleT    627         const G4double massnucleon = ParticleTable::getRealMass(Proton);        
628                                                   628 
629         G4double plab=KinematicsUtils::momentu    629         G4double plab=KinematicsUtils::momentumInLab(ECM*ECM, masspion, massnucleon)/1000.;  // GeV/c
630                                                   630         
631         G4double sigma;                           631         G4double sigma;
632         if (plab < param) sigma=0.;               632         if (plab < param) sigma=0.;
633         else sigma=13.76*(plab-param)/(std::po    633         else sigma=13.76*(plab-param)/(std::pow(plab, 3.33)-1.07);
634                                                   634         
635         return sigma;                             635         return sigma;
636     }                                             636     }
637                                                   637 
638     G4double CrossSectionsMultiPionsAndResonan    638     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaIso(const G4double ener, const G4int iso) {
639                                                   639 
640         const G4double Ecm=0.001*ener;            640         const G4double Ecm=0.001*ener;
641         G4double sNNEta; // pp->pp+eta(+X)        641         G4double sNNEta; // pp->pp+eta(+X)
642         G4double sNNEta1; // np->np+eta(+X)       642         G4double sNNEta1; // np->np+eta(+X)
643         G4double sNNEta2; // np->d+eta (d will    643         G4double sNNEta2; // np->d+eta (d will be considered as np - How far is this right?)
644         G4double x=Ecm*Ecm/5.88;                  644         G4double x=Ecm*Ecm/5.88;
645                                                   645             
646 //jcd                                             646 //jcd
647         if (Ecm >= 3.05) {                        647         if (Ecm >= 3.05) {
648             sNNEta = 2.5*std::pow((x-1.),1.47)    648             sNNEta = 2.5*std::pow((x-1.),1.47)*std::pow(x,-1.25)*1000.;
649         }                                         649         }      
650         else if(Ecm >= 2.6) {                     650         else if(Ecm >= 2.6) {
651             sNNEta = -327.29*Ecm*Ecm*Ecm + 287    651             sNNEta = -327.29*Ecm*Ecm*Ecm + 2870.*Ecm*Ecm - 7229.3*Ecm + 5273.3;
652             if (sNNEta <= NNToNNEtaExcluIso(en    652             if (sNNEta <= NNToNNEtaExcluIso(ener, 2)*1000.) sNNEta = NNToNNEtaExcluIso(ener, 2)*1000.;
653         }                                         653         }
654         else {                                    654         else {
655             sNNEta = NNToNNEtaExcluIso(ener, 2    655             sNNEta = NNToNNEtaExcluIso(ener, 2)*1000.;
656         }                                         656         }
657 //jcd                                             657 //jcd
658         if (sNNEta < 1.e-9) sNNEta = 0.;          658         if (sNNEta < 1.e-9) sNNEta = 0.;
659                                                   659 
660         if (iso != 0) {                           660         if (iso != 0) {
661             return sNNEta/1000.; // parameteri    661             return sNNEta/1000.; // parameterization in microbarn (not millibarn)!
662         }                                         662         }
663                                                   663 
664         if(Ecm >= 6.25) {                         664         if(Ecm >= 6.25) {
665             sNNEta1 = sNNEta;                     665             sNNEta1 = sNNEta;
666         }                                         666         }
667         else if (Ecm >= 2.6) {                    667         else if (Ecm >= 2.6) {
668             sNNEta1 = sNNEta*std::exp(-(-5.531    668             sNNEta1 = sNNEta*std::exp(-(-5.53151576/Ecm+0.8850425));
669         }                                         669         }
670         else if (Ecm >= 2.525) { // = exclusiv    670         else if (Ecm >= 2.525) { // = exclusive pn
671             sNNEta1 = -4433.586*Ecm*Ecm*Ecm*Ec    671             sNNEta1 = -4433.586*Ecm*Ecm*Ecm*Ecm + 56581.54*Ecm*Ecm*Ecm - 270212.6*Ecm*Ecm + 571650.6*Ecm - 451091.6;
672         }                                         672         }
673         else { // = exclusive pn                  673         else { // = exclusive pn
674             sNNEta1 = 17570.217219*Ecm*Ecm - 8    674             sNNEta1 = 17570.217219*Ecm*Ecm - 84910.985402*Ecm + 102585.55847;
675         }                                         675         }
676                                                   676 
677         sNNEta2 = -10220.89518466*Ecm*Ecm+5122    677         sNNEta2 = -10220.89518466*Ecm*Ecm+51227.30841724*Ecm-64097.96025731;
678         if (sNNEta2 < 0.) sNNEta2=0.;             678         if (sNNEta2 < 0.) sNNEta2=0.;
679                                                   679 
680         sNNEta = 2*(sNNEta1+sNNEta2)-sNNEta;      680         sNNEta = 2*(sNNEta1+sNNEta2)-sNNEta;
681                                                   681 
682         G4double Mn=ParticleTable::getRealMass    682         G4double Mn=ParticleTable::getRealMass(Neutron)/1000.;
683         G4double Mp=ParticleTable::getRealMass    683         G4double Mp=ParticleTable::getRealMass(Proton)/1000.;
684         G4double Meta=ParticleTable::getRealMa    684         G4double Meta=ParticleTable::getRealMass(Eta)/1000.;
685         if (sNNEta < 1.e-9 || Ecm < Mn+Mp+Meta    685         if (sNNEta < 1.e-9 || Ecm < Mn+Mp+Meta) sNNEta = 0.;
686                                                   686 
687         return sNNEta/1000.; // parameterizati    687         return sNNEta/1000.; // parameterization in microbarn (not millibarn)!
688     }                                             688     }
689                                                   689 
690                                                   690     
691     G4double CrossSectionsMultiPionsAndResonan    691     G4double CrossSectionsMultiPionsAndResonances::NNToNNEta(Particle const * const particle1, Particle const * const particle2) {
692                                                   692 
693         const G4double ener=KinematicsUtils::t    693         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2);
694         const G4int iso=ParticleTable::getIsos    694         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
695                                                   695 
696         if (iso != 0) {                           696         if (iso != 0) {
697             return NNToNNEtaIso(ener, iso);       697             return NNToNNEtaIso(ener, iso);
698         }                                         698         }
699         else {                                    699         else {
700             return 0.5*(NNToNNEtaIso(ener, 0)+    700             return 0.5*(NNToNNEtaIso(ener, 0)+NNToNNEtaIso(ener, 2));
701         }                                         701         }
702     }                                             702     }
703                                                   703 
704     G4double CrossSectionsMultiPionsAndResonan    704     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaExcluIso(const G4double ener, const G4int iso) {
705                                                   705 
706         const G4double Ecm=0.001*ener;            706         const G4double Ecm=0.001*ener;
707         G4double sNNEta; // pp->pp+eta            707         G4double sNNEta; // pp->pp+eta
708         G4double sNNEta1; // np->np+eta           708         G4double sNNEta1; // np->np+eta
709         G4double sNNEta2; // np->d+eta (d wil     709         G4double sNNEta2; // np->d+eta (d wil be considered as np - How far is this right?)
710                                                   710 
711         if(Ecm>=3.875) { // By hand (JCD)         711         if(Ecm>=3.875) { // By hand (JCD)
712             sNNEta = -13.008*Ecm*Ecm + 84.531*    712             sNNEta = -13.008*Ecm*Ecm + 84.531*Ecm + 36.234;
713         }                                         713         }
714         else if(Ecm>=2.725) { // By hand (JCD)    714         else if(Ecm>=2.725) { // By hand (JCD)
715             sNNEta = -913.2809*std::pow(Ecm,5)    715             sNNEta = -913.2809*std::pow(Ecm,5) + 15564.27*std::pow(Ecm,4) - 105054.9*std::pow(Ecm,3) + 351294.2*std::pow(Ecm,2) - 582413.9*Ecm + 383474.7;
716         }                                         716         }
717         else if(Ecm>=2.575) { // By hand (JCD)    717         else if(Ecm>=2.575) { // By hand (JCD)
718             sNNEta = -2640.3*Ecm*Ecm + 14692*E    718             sNNEta = -2640.3*Ecm*Ecm + 14692*Ecm - 20225;
719         }                                         719         }
720         else {                                    720         else {
721             sNNEta = -147043.497285*std::pow(E    721             sNNEta = -147043.497285*std::pow(Ecm,4) + 1487222.5438123*std::pow(Ecm,3) - 5634399.900744*std::pow(Ecm,2) + 9477290.199378*Ecm - 5972174.353438;
722         }                                         722         }
723                                                   723 
724         G4double Mn=ParticleTable::getRealMass    724         G4double Mn=ParticleTable::getRealMass(Neutron)/1000.;
725         G4double Mp=ParticleTable::getRealMass    725         G4double Mp=ParticleTable::getRealMass(Proton)/1000.;
726         G4double Meta=ParticleTable::getRealMa    726         G4double Meta=ParticleTable::getRealMass(Eta)/1000.;
727         G4double Thr0=0.;                         727         G4double Thr0=0.;
728         if (iso > 0) {                            728         if (iso > 0) {
729             Thr0=2.*Mp+Meta;                      729             Thr0=2.*Mp+Meta;
730         }                                         730         }
731         else if (iso < 0) {                       731         else if (iso < 0) {
732             Thr0=2.*Mn+Meta;                      732             Thr0=2.*Mn+Meta;
733         }                                         733         }
734         else {                                    734         else {
735             Thr0=Mn+Mp+Meta;                      735             Thr0=Mn+Mp+Meta;
736         }                                         736         }
737                                                   737 
738         if (sNNEta < 1.e-9 || Ecm < Thr0) sNNE    738         if (sNNEta < 1.e-9 || Ecm < Thr0) sNNEta = 0.;  // Thr0: Ecm threshold
739                                                   739 
740         if (iso != 0) {                           740         if (iso != 0) {
741             return sNNEta/1000.; // parameteri    741             return sNNEta/1000.; // parameterization in microbarn (not millibarn)!
742         }                                         742         }
743                                                   743 
744         if(Ecm>=3.9) {                            744         if(Ecm>=3.9) {
745             sNNEta1 = sNNEta;                     745             sNNEta1 = sNNEta;
746         }                                         746         }
747         else if (Ecm >= 3.5) {                    747         else if (Ecm >= 3.5) {
748             sNNEta1 = -1916.2*Ecm*Ecm*Ecm + 21    748             sNNEta1 = -1916.2*Ecm*Ecm*Ecm + 21556.0*Ecm*Ecm - 80828.0*Ecm + 101200.0;
749         }                                         749         }
750         else if (Ecm >= 2.525) {                  750         else if (Ecm >= 2.525) {
751             sNNEta1 = -4433.586*Ecm*Ecm*Ecm*Ec    751             sNNEta1 = -4433.586*Ecm*Ecm*Ecm*Ecm + 56581.54*Ecm*Ecm*Ecm - 270212.6*Ecm*Ecm + 571650.6*Ecm - 451091.6;
752         }                                         752         }
753         else {                                    753         else {
754             sNNEta1 = 17570.217219*Ecm*Ecm - 8    754             sNNEta1 = 17570.217219*Ecm*Ecm - 84910.985402*Ecm + 102585.55847;
755         }                                         755         }
756                                                   756 
757         sNNEta2 = -10220.89518466*Ecm*Ecm+5122    757         sNNEta2 = -10220.89518466*Ecm*Ecm+51227.30841724*Ecm-64097.96025731;
758         if (sNNEta2 < 0.) sNNEta2=0.;             758         if (sNNEta2 < 0.) sNNEta2=0.;
759                                                   759 
760         sNNEta = 2*(sNNEta1+sNNEta2)-sNNEta;      760         sNNEta = 2*(sNNEta1+sNNEta2)-sNNEta;
761         if (sNNEta < 1.e-9 || Ecm < Thr0) sNNE    761         if (sNNEta < 1.e-9 || Ecm < Thr0) sNNEta = 0.;  // Thr0: Ecm threshold
762                                                   762 
763         return sNNEta/1000.; // parameterizati    763         return sNNEta/1000.; // parameterization in microbarn (not millibarn)!
764                                                   764 
765     }                                             765     }
766                                                   766 
767     G4double CrossSectionsMultiPionsAndResonan    767     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaExclu(Particle const * const particle1, Particle const * const particle2) {
768                                                   768 
769         const G4double ener=KinematicsUtils::t    769         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2);
770         const G4int iso=ParticleTable::getIsos    770         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
771                                                   771 
772         if (iso != 0) {                           772         if (iso != 0) {
773             return NNToNNEtaExcluIso(ener, iso    773             return NNToNNEtaExcluIso(ener, iso);
774         }                                         774         }
775         else {                                    775         else {
776             return 0.5*(NNToNNEtaExcluIso(ener    776             return 0.5*(NNToNNEtaExcluIso(ener, 0)+NNToNNEtaExcluIso(ener, 2));
777         }                                         777         }
778     }                                             778     }
779                                                   779 
780                                                   780 
781     G4double CrossSectionsMultiPionsAndResonan    781     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaIso(const G4double ener, const G4int iso) {
782                                                   782 
783         const G4double Ecm=0.001*ener;            783         const G4double Ecm=0.001*ener;
784         G4double sNNOmega; // pp->pp+eta(+X)      784         G4double sNNOmega; // pp->pp+eta(+X)
785         G4double sNNOmega1; // np->np+eta(+X)     785         G4double sNNOmega1; // np->np+eta(+X)
786         G4double x=Ecm*Ecm/7.06;                  786         G4double x=Ecm*Ecm/7.06;
787                                                   787 
788         if(Ecm>4.0) {                             788         if(Ecm>4.0) {
789             sNNOmega = 2.5*std::pow(x-1, 1.47)    789             sNNOmega = 2.5*std::pow(x-1, 1.47)*std::pow(x, -1.11) ;
790         }                                         790         }
791         else if(Ecm>2.802) { // 2802 MeV -> th    791         else if(Ecm>2.802) { // 2802 MeV -> threshold to open inclusive (based on multipion threshold and omega mass) 
792             sNNOmega = (568.5254*Ecm*Ecm - 269    792             sNNOmega = (568.5254*Ecm*Ecm - 2694.045*Ecm + 3106.247)/1000.;
793         if (sNNOmega <= NNToNNOmegaExcluIso(en    793         if (sNNOmega <= NNToNNOmegaExcluIso(ener, 2)) sNNOmega = NNToNNOmegaExcluIso(ener, 2);
794         }                                         794         }
795         else {                                    795         else {
796             sNNOmega = NNToNNOmegaExcluIso(ene    796             sNNOmega = NNToNNOmegaExcluIso(ener, 2);
797         }                                         797         }
798                                                   798 
799         if (sNNOmega < 1.e-9) sNNOmega = 0.;      799         if (sNNOmega < 1.e-9) sNNOmega = 0.;
800                                                   800 
801         if (iso != 0) {                           801         if (iso != 0) {
802         return sNNOmega;                          802         return sNNOmega; 
803         }                                         803         }
804                                                   804 
805         sNNOmega1 = 3.*sNNOmega; // 3.0: ratio    805         sNNOmega1 = 3.*sNNOmega; // 3.0: ratio pn/pp (5 from theory; 2 from experiments)
806                                                   806 
807         sNNOmega = 2.*sNNOmega1-sNNOmega;         807         sNNOmega = 2.*sNNOmega1-sNNOmega;
808                                                   808 
809         if (sNNOmega < 1.e-9) sNNOmega = 0.;      809         if (sNNOmega < 1.e-9) sNNOmega = 0.;
810                                                   810 
811         return sNNOmega;                          811         return sNNOmega; 
812     }                                             812     }
813                                                   813 
814                                                   814 
815     G4double CrossSectionsMultiPionsAndResonan    815     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmega(Particle const * const particle1, Particle const * const particle2) {
816                                                   816 
817         const G4double ener=KinematicsUtils::t    817         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2);
818         const G4int iso=ParticleTable::getIsos    818         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
819 //jcd to be removed                               819 //jcd to be removed
820 //        return 0.;                              820 //        return 0.;
821 //jcd                                             821 //jcd    
822         if (iso != 0) {                           822         if (iso != 0) {
823             return NNToNNOmegaIso(ener, iso);     823             return NNToNNOmegaIso(ener, iso);
824         }                                         824         }
825         else {                                    825         else {
826             return 0.5*(NNToNNOmegaIso(ener, 0    826             return 0.5*(NNToNNOmegaIso(ener, 0)+NNToNNOmegaIso(ener, 2));
827         }                                         827         }
828     }                                             828     }
829                                                   829 
830     G4double CrossSectionsMultiPionsAndResonan    830     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaExcluIso(const G4double ener, const G4int iso) {
831                                                   831 
832         const G4double Ecm=0.001*ener;            832         const G4double Ecm=0.001*ener;
833         G4double sNNOmega; // pp->pp+eta          833         G4double sNNOmega; // pp->pp+eta
834         G4double sNNOmega1; // np->np+eta         834         G4double sNNOmega1; // np->np+eta
835         G4double sthroot=std::sqrt(7.06);         835         G4double sthroot=std::sqrt(7.06);
836                                                   836 
837         if(Ecm>=3.0744) { // By hand (JCD)        837         if(Ecm>=3.0744) { // By hand (JCD)
838             sNNOmega = 330.*(Ecm-sthroot)/(1.0    838             sNNOmega = 330.*(Ecm-sthroot)/(1.05+std::pow((Ecm-sthroot),2));
839         }                                         839         }
840         else if(Ecm>=2.65854){                    840         else if(Ecm>=2.65854){
841             sNNOmega = -1208.09757*std::pow(Ec    841             sNNOmega = -1208.09757*std::pow(Ecm,3) + 10773.3322*std::pow(Ecm,2) - 31661.0223*Ecm + 30728.7241 ;
842         }                                         842         }
843         else {                                    843         else {
844             sNNOmega = 0. ;                       844             sNNOmega = 0. ;
845         }                                         845         }
846                                                   846 
847         G4double Mn=ParticleTable::getRealMass    847         G4double Mn=ParticleTable::getRealMass(Neutron)/1000.;
848         G4double Mp=ParticleTable::getRealMass    848         G4double Mp=ParticleTable::getRealMass(Proton)/1000.;
849         G4double Momega=ParticleTable::getReal    849         G4double Momega=ParticleTable::getRealMass(Omega)/1000.;
850         G4double Thr0=0.;                         850         G4double Thr0=0.;
851         if (iso > 0) {                            851         if (iso > 0) {
852             Thr0=2.*Mp+Momega;                    852             Thr0=2.*Mp+Momega;
853         }                                         853         }
854         else if (iso < 0) {                       854         else if (iso < 0) {
855             Thr0=2.*Mn+Momega;                    855             Thr0=2.*Mn+Momega;
856         }                                         856         }
857         else {                                    857         else {
858             Thr0=Mn+Mp+Momega;                    858             Thr0=Mn+Mp+Momega;
859         }                                         859         }
860                                                   860 
861         if (sNNOmega < 1.e-9 || Ecm < Thr0) sN    861         if (sNNOmega < 1.e-9 || Ecm < Thr0) sNNOmega = 0.;  // Thr0: Ecm threshold
862                                                   862 
863         if (iso != 0) {                           863         if (iso != 0) {
864             return sNNOmega/1000.; // paramete    864             return sNNOmega/1000.; // parameterization in microbarn (not millibarn)!
865         }                                         865         }
866                                                   866 
867         sNNOmega1 = 3*sNNOmega; // 3.0: ratio     867         sNNOmega1 = 3*sNNOmega; // 3.0: ratio pn/pp
868                                                   868 
869         sNNOmega = 2*sNNOmega1-sNNOmega;          869         sNNOmega = 2*sNNOmega1-sNNOmega;
870         if (sNNOmega < 1.e-9 || Ecm < Thr0) sN    870         if (sNNOmega < 1.e-9 || Ecm < Thr0) sNNOmega = 0.;
871                                                   871 
872         return sNNOmega/1000.; // parameteriza    872         return sNNOmega/1000.; // parameterization in microbarn (not millibarn)!
873     }                                             873     }
874                                                   874 
875     G4double CrossSectionsMultiPionsAndResonan    875     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaExclu(Particle const * const particle1, Particle const * const particle2) {
876 //jcd to be removed                               876 //jcd to be removed
877 //        return 0.;                              877 //        return 0.;
878 //jcd                                             878 //jcd    
879                                                   879 
880         const G4double ener=KinematicsUtils::t    880         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2);
881         const G4int iso=ParticleTable::getIsos    881         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
882                                                   882 
883         if (iso != 0) {                           883         if (iso != 0) {
884             return NNToNNOmegaExcluIso(ener, i    884             return NNToNNOmegaExcluIso(ener, iso);
885         }                                         885         }
886         else {                                    886         else {
887             return 0.5*(NNToNNOmegaExcluIso(en    887             return 0.5*(NNToNNOmegaExcluIso(ener, 0)+NNToNNOmegaExcluIso(ener, 2));
888         }                                         888         }
889     }                                             889     }
890                                                   890 
891                                                   891 
892     G4double CrossSectionsMultiPionsAndResonan    892     G4double CrossSectionsMultiPionsAndResonances::NNToxPiNN(const G4int xpi, Particle const * const particle1, Particle const * const particle2) {
893         //                                        893         //
894         //     Nucleon-Nucleon producing xpi p    894         //     Nucleon-Nucleon producing xpi pions cross sections
895         //                                        895         //
896 // assert(xpi>0 && xpi<=nMaxPiNN);                896 // assert(xpi>0 && xpi<=nMaxPiNN);
897 // assert(particle1->isNucleon() && particle2-    897 // assert(particle1->isNucleon() && particle2->isNucleon());
898                                                   898 
899         G4double oldXS1Pi=CrossSectionsMultiPi    899         G4double oldXS1Pi=CrossSectionsMultiPions::NNToxPiNN(1,particle1, particle2);
900         G4double oldXS2Pi=CrossSectionsMultiPi    900         G4double oldXS2Pi=CrossSectionsMultiPions::NNToxPiNN(2,particle1, particle2);
901         G4double oldXS3Pi=CrossSectionsMultiPi    901         G4double oldXS3Pi=CrossSectionsMultiPions::NNToxPiNN(3,particle1, particle2);
902         G4double oldXS4Pi=CrossSectionsMultiPi    902         G4double oldXS4Pi=CrossSectionsMultiPions::NNToxPiNN(4,particle1, particle2);
903         G4double xsEtaOmega=NNToNNEta(particle    903         G4double xsEtaOmega=NNToNNEta(particle1, particle2)+NNToNNOmega(particle1, particle2);
904         G4double newXS1Pi=0.;                     904         G4double newXS1Pi=0.;    
905         G4double newXS2Pi=0.;                     905         G4double newXS2Pi=0.;    
906         G4double newXS3Pi=0.;                     906         G4double newXS3Pi=0.;    
907         G4double newXS4Pi=0.;                     907         G4double newXS4Pi=0.;    
908                                                   908 
909         if (xpi == 1) {                           909         if (xpi == 1) {
910             if (oldXS4Pi != 0. || oldXS3Pi !=     910             if (oldXS4Pi != 0. || oldXS3Pi != 0.)
911                 newXS1Pi=oldXS1Pi;                911                 newXS1Pi=oldXS1Pi;
912             else if (oldXS2Pi != 0.) {            912             else if (oldXS2Pi != 0.) {
913                 newXS2Pi=oldXS2Pi-xsEtaOmega;     913                 newXS2Pi=oldXS2Pi-xsEtaOmega;
914                 if (newXS2Pi < 0.)                914                 if (newXS2Pi < 0.)
915                     newXS1Pi=oldXS1Pi-(xsEtaOm    915                     newXS1Pi=oldXS1Pi-(xsEtaOmega-oldXS2Pi);
916                 else                              916                 else
917                     newXS1Pi=oldXS1Pi;            917                     newXS1Pi=oldXS1Pi;
918             }                                     918             }
919             else                                  919             else 
920                 newXS1Pi=oldXS1Pi-xsEtaOmega;     920                 newXS1Pi=oldXS1Pi-xsEtaOmega;
921             return newXS1Pi;                      921             return newXS1Pi;
922         }                                         922         }
923         else if (xpi == 2) {                      923         else if (xpi == 2) {
924             if (oldXS4Pi != 0.)                   924             if (oldXS4Pi != 0.)
925             newXS2Pi=oldXS2Pi;                    925             newXS2Pi=oldXS2Pi;
926             else if (oldXS3Pi != 0.) {            926             else if (oldXS3Pi != 0.) {
927                 newXS3Pi=oldXS3Pi-xsEtaOmega;     927                 newXS3Pi=oldXS3Pi-xsEtaOmega;
928                 if (newXS3Pi < 0.)                928                 if (newXS3Pi < 0.)
929                     newXS2Pi=oldXS2Pi-(xsEtaOm    929                     newXS2Pi=oldXS2Pi-(xsEtaOmega-oldXS3Pi);
930                 else                              930                 else
931                     newXS2Pi=oldXS2Pi;            931                     newXS2Pi=oldXS2Pi;
932             }                                     932             }
933             else {                                933             else { 
934                 newXS2Pi=oldXS2Pi-xsEtaOmega;     934                 newXS2Pi=oldXS2Pi-xsEtaOmega;
935                 if (newXS2Pi < 0.)                935                 if (newXS2Pi < 0.)
936                     newXS2Pi=0.;                  936                     newXS2Pi=0.;
937             }                                     937             }
938             return newXS2Pi;                      938             return newXS2Pi;
939         }                                         939         }
940         else if (xpi == 3) {                      940         else if (xpi == 3) {
941             if (oldXS4Pi != 0.) {                 941             if (oldXS4Pi != 0.) {
942                 newXS4Pi=oldXS4Pi-xsEtaOmega;     942                 newXS4Pi=oldXS4Pi-xsEtaOmega;
943                 if (newXS4Pi < 0.)                943                 if (newXS4Pi < 0.)
944                     newXS3Pi=oldXS3Pi-(xsEtaOm    944                     newXS3Pi=oldXS3Pi-(xsEtaOmega-oldXS4Pi);
945                 else                              945                 else
946                     newXS3Pi=oldXS3Pi;            946                     newXS3Pi=oldXS3Pi;
947             }                                     947             }
948             else {                                948             else { 
949                 newXS3Pi=oldXS3Pi-xsEtaOmega;     949                 newXS3Pi=oldXS3Pi-xsEtaOmega;                
950                 if (newXS3Pi < 0.)                950                 if (newXS3Pi < 0.)
951                     newXS3Pi=0.;                  951                     newXS3Pi=0.;
952             }                                     952             }
953             return newXS3Pi;                      953             return newXS3Pi;
954         }                                         954         }
955         else if (xpi == 4) {                      955         else if (xpi == 4) {
956             newXS4Pi=oldXS4Pi-xsEtaOmega;         956             newXS4Pi=oldXS4Pi-xsEtaOmega;
957             if (newXS4Pi < 0.)                    957             if (newXS4Pi < 0.)
958                 newXS4Pi=0.;                      958                 newXS4Pi=0.;
959             return newXS4Pi;                      959             return newXS4Pi;
960         }                                         960         }
961                                                   961 
962         else // should never reach this point     962         else // should never reach this point
963         return 0.;                                963         return 0.;
964     }                                             964     }
965                                                   965 
966                                                   966 
967     G4double CrossSectionsMultiPionsAndResonan    967     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaOnePi(Particle const * const particle1, Particle const * const particle2) {
968         // Cross section for nucleon-nucleon p    968         // Cross section for nucleon-nucleon producing one eta and one pion
969                                                   969 
970         const G4int iso=ParticleTable::getIsos    970         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
971         if (iso!=0)                               971         if (iso!=0)
972             return 0.;                            972             return 0.;
973                                                   973 
974         const G4double ener=KinematicsUtils::t    974         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 581.437; // 581.437 MeV translation to open pion production in NNEta (= 2705.55 - 2018.563; 4074595.287720512986=2018.563*2018.563)
975         if (ener < 2018.563) return 0.;           975         if (ener < 2018.563) return 0.;
976                                                   976 
977         const G4double xsiso2=CrossSectionsMul    977         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
978         const G4double xsiso0=CrossSectionsMul    978         const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
979                                                   979 
980         return 0.25*(CrossSectionsMultiPions::    980         return 0.25*(CrossSectionsMultiPions::NNOnePiOrDelta(ener, 0, xsiso0)+ CrossSectionsMultiPions::NNOnePiOrDelta(ener, 2, xsiso2));
981     }                                             981     }
982                                                   982 
983     G4double CrossSectionsMultiPionsAndResonan    983     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaOnePiOrDelta(Particle const * const particle1, Particle const * const particle2) {
984         const G4double ener=KinematicsUtils::t    984         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 581.437; // 581.437 MeV translation to open pion production in NNEta
985         if (ener < 2018.563) return 0.;           985         if (ener < 2018.563) return 0.;
986         const G4int iso=ParticleTable::getIsos    986         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
987                                                   987 
988         const G4double xsiso2=CrossSectionsMul    988         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
989         if (iso != 0)                             989         if (iso != 0)
990             return CrossSectionsMultiPions::NN    990             return CrossSectionsMultiPions::NNOnePiOrDelta(ener, iso, xsiso2);
991         else {                                    991         else {
992             const G4double xsiso0=CrossSection    992             const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
993             return 0.5*(CrossSectionsMultiPion    993             return 0.5*(CrossSectionsMultiPions::NNOnePiOrDelta(ener, 0, xsiso0)+ CrossSectionsMultiPions::NNOnePiOrDelta(ener, 2, xsiso2));
994         }                                         994         }
995     }                                             995     }
996                                                   996 
997     G4double CrossSectionsMultiPionsAndResonan    997     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaTwoPi(Particle const * const particle1, Particle const * const particle2) {
998         //                                        998         //
999         //     Nucleon-Nucleon producing one e    999         //     Nucleon-Nucleon producing one eta and two pions 
1000         //                                       1000         //
1001         const G4double ener=KinematicsUtils::    1001         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 581.437; // 581.437 MeV translation to open pion production in NNEta
1002         if (ener < 2018.563) return 0.;          1002         if (ener < 2018.563) return 0.;
1003         const G4int iso=ParticleTable::getIso    1003         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1004                                                  1004 
1005                                                  1005 
1006         const G4double xsiso2=CrossSectionsMu    1006         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1007         if (iso != 0) {                          1007         if (iso != 0) {
1008             return CrossSectionsMultiPions::N    1008             return CrossSectionsMultiPions::NNTwoPi(ener, 2, xsiso2);
1009         }                                        1009         }
1010         else {                                   1010         else {
1011             const G4double xsiso0=CrossSectio    1011             const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
1012             return 0.5*(CrossSectionsMultiPio    1012             return 0.5*(CrossSectionsMultiPions::NNTwoPi(ener, 0, xsiso0)+ CrossSectionsMultiPions::NNTwoPi(ener, 2, xsiso2));
1013         }                                        1013         }
1014     }                                            1014     }
1015                                                  1015 
1016     G4double CrossSectionsMultiPionsAndResona    1016     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaThreePi(Particle const * const particle1, Particle const * const particle2) {
1017         //                                       1017         //
1018         //     Nucleon-Nucleon producing one     1018         //     Nucleon-Nucleon producing one eta and three pions
1019         //                                       1019         //
1020                                                  1020 
1021         const G4double ener=KinematicsUtils::    1021         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 581.437; // 581.437 MeV translation to open pion production in NNEta
1022         if (ener < 2018.563) return 0.;          1022         if (ener < 2018.563) return 0.;
1023         const G4int iso=ParticleTable::getIso    1023         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1024                                                  1024 
1025                                                  1025 
1026         const G4double xsiso2=CrossSectionsMu    1026         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1027         const G4double xs1pi2=CrossSectionsMu    1027         const G4double xs1pi2=CrossSectionsMultiPions::NNOnePiOrDelta(ener, 2, xsiso2);
1028         const G4double xs2pi2=CrossSectionsMu    1028         const G4double xs2pi2=CrossSectionsMultiPions::NNTwoPi(ener, 2, xsiso2);
1029         if (iso != 0)                            1029         if (iso != 0)
1030             return CrossSectionsMultiPions::N    1030             return CrossSectionsMultiPions::NNThreePi(ener, 2, xsiso2, xs1pi2, xs2pi2);
1031         else {                                   1031         else {
1032             const G4double xsiso0=CrossSectio    1032             const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
1033             const G4double xs1pi0=CrossSectio    1033             const G4double xs1pi0=CrossSectionsMultiPions::NNOnePiOrDelta(ener, 0, xsiso0);
1034             const G4double xs2pi0=CrossSectio    1034             const G4double xs2pi0=CrossSectionsMultiPions::NNTwoPi(ener, 0, xsiso0);
1035             return 0.5*(CrossSectionsMultiPio    1035             return 0.5*(CrossSectionsMultiPions::NNThreePi(ener, 0, xsiso0, xs1pi0, xs2pi0)+ CrossSectionsMultiPions::NNThreePi(ener, 2, xsiso2, xs1pi2, xs2pi2));
1036         }                                        1036         }
1037     }                                            1037     }
1038                                                  1038 
1039     G4double CrossSectionsMultiPionsAndResona    1039     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaFourPi(Particle const * const particle1, Particle const * const particle2) {
1040         //                                       1040         //
1041         //     Nucleon-Nucleon producing one     1041         //     Nucleon-Nucleon producing one eta and four pions
1042         //                                       1042         //
1043                                                  1043 
1044         const G4double ener=KinematicsUtils::    1044         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 581.437; // 581.437 MeV translation to open pion production in NNEta
1045         if (ener < 2018.563) return 0.;          1045         if (ener < 2018.563) return 0.;
1046         const G4double s = ener*ener;            1046         const G4double s = ener*ener;
1047         const G4int i = ParticleTable::getIso    1047         const G4int i = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1048         G4double xsinelas;                       1048         G4double xsinelas;
1049         if (i!=0)                                1049         if (i!=0) 
1050             xsinelas=CrossSectionsMultiPions:    1050             xsinelas=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1051         else                                     1051         else 
1052             xsinelas=0.5*(CrossSectionsMultiP    1052             xsinelas=0.5*(CrossSectionsMultiPions::NNInelasticIso(ener, 0)+CrossSectionsMultiPions::NNInelasticIso(ener, 2));
1053         if (xsinelas <= 1.e-9) return 0.;        1053         if (xsinelas <= 1.e-9) return 0.;
1054         G4double ratio=(NNToNNEta(particle1,     1054         G4double ratio=(NNToNNEta(particle1, particle2)-NNToNNEtaExclu(particle1, particle2))/xsinelas;
1055         if(s<6.25E6)                             1055         if(s<6.25E6)
1056             return 0.;                           1056             return 0.;
1057         const G4double sigma = NNToNNEta(part    1057         const G4double sigma = NNToNNEta(particle1, particle2) - NNToNNEtaExclu(particle1, particle2) - ratio*(NNToNNEtaOnePiOrDelta(particle1, particle2) + NNToNNEtaTwoPi(particle1, particle2) + NNToNNEtaThreePi(particle1, particle2));
1058         return ((sigma>1.e-9) ? sigma : 0.);     1058         return ((sigma>1.e-9) ? sigma : 0.);
1059     }                                            1059     }
1060                                                  1060 
1061     G4double CrossSectionsMultiPionsAndResona    1061     G4double CrossSectionsMultiPionsAndResonances::NNToNNEtaxPi(const G4int xpi, Particle const * const particle1, Particle const * const particle2) {
1062         //                                       1062         //
1063         //     Nucleon-Nucleon producing one     1063         //     Nucleon-Nucleon producing one eta and xpi pions
1064         //                                       1064         //
1065 // assert(xpi>0 && xpi<=nMaxPiNN);               1065 // assert(xpi>0 && xpi<=nMaxPiNN);
1066 // assert(particle1->isNucleon() && particle2    1066 // assert(particle1->isNucleon() && particle2->isNucleon());
1067                                                  1067 
1068         const G4double ener=KinematicsUtils::    1068         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 581.437; // 581.437 MeV translation to open pion production in NNEta
1069         if (ener < 2018.563) return 0.;          1069         if (ener < 2018.563) return 0.;
1070         const G4int i = ParticleTable::getIso    1070         const G4int i = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1071         G4double xsinelas;                       1071         G4double xsinelas;
1072         if (i!=0)                                1072         if (i!=0) 
1073             xsinelas=CrossSectionsMultiPions:    1073             xsinelas=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1074         else                                     1074         else 
1075             xsinelas=0.5*(CrossSectionsMultiP    1075             xsinelas=0.5*(CrossSectionsMultiPions::NNInelasticIso(ener, 0)+CrossSectionsMultiPions::NNInelasticIso(ener, 2));
1076         if (xsinelas <= 1.e-9) return 0.;        1076         if (xsinelas <= 1.e-9) return 0.;
1077         G4double ratio=(NNToNNEta(particle1,     1077         G4double ratio=(NNToNNEta(particle1, particle2)-NNToNNEtaExclu(particle1, particle2))/xsinelas;
1078                                                  1078 
1079         if (xpi == 1)                            1079         if (xpi == 1)
1080             return NNToNNEtaOnePi(particle1,     1080             return NNToNNEtaOnePi(particle1, particle2)*ratio;
1081         else if (xpi == 2)                       1081         else if (xpi == 2)
1082             return NNToNNEtaTwoPi(particle1,     1082             return NNToNNEtaTwoPi(particle1, particle2)*ratio;
1083         else if (xpi == 3)                       1083         else if (xpi == 3)
1084             return NNToNNEtaThreePi(particle1    1084             return NNToNNEtaThreePi(particle1, particle2)*ratio;
1085         else if (xpi == 4)                       1085         else if (xpi == 4)
1086             return NNToNNEtaFourPi(particle1,    1086             return NNToNNEtaFourPi(particle1, particle2);
1087         else // should never reach this point    1087         else // should never reach this point
1088             return 0.;                           1088             return 0.;
1089     }                                            1089     }
1090                                                  1090 
1091                                                  1091 
1092     G4double CrossSectionsMultiPionsAndResona    1092     G4double CrossSectionsMultiPionsAndResonances::NNToNDeltaEta(Particle const * const p1, Particle const * const p2) {
1093 // assert(p1->isNucleon() && p2->isNucleon())    1093 // assert(p1->isNucleon() && p2->isNucleon());
1094         const G4int i = ParticleTable::getIso    1094         const G4int i = ParticleTable::getIsospin(p1->getType()) + ParticleTable::getIsospin(p2->getType());
1095         const G4double ener=KinematicsUtils::    1095         const G4double ener=KinematicsUtils::totalEnergyInCM(p1, p2) - 581.437; // 581.437 MeV translation to open pion production in NNEta
1096         if (ener < 2018.563) return 0.;          1096         if (ener < 2018.563) return 0.;
1097         G4double xsinelas;                       1097         G4double xsinelas;
1098         if (i!=0)                                1098         if (i!=0) 
1099             xsinelas=CrossSectionsMultiPions:    1099             xsinelas=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1100         else                                     1100         else 
1101             xsinelas=0.5*(CrossSectionsMultiP    1101             xsinelas=0.5*(CrossSectionsMultiPions::NNInelasticIso(ener, 0)+CrossSectionsMultiPions::NNInelasticIso(ener, 2));
1102         if (xsinelas <= 1.e-9) return 0.;        1102         if (xsinelas <= 1.e-9) return 0.;
1103         G4double ratio=(NNToNNEta(p1, p2)-NNT    1103         G4double ratio=(NNToNNEta(p1, p2)-NNToNNEtaExclu(p1, p2))/xsinelas;
1104         G4double sigma = NNToNNEtaOnePiOrDelt    1104         G4double sigma = NNToNNEtaOnePiOrDelta(p1, p2)*ratio;
1105         if(i==0)                                 1105         if(i==0)
1106             sigma *= 0.5;                        1106             sigma *= 0.5;
1107         return sigma;                            1107         return sigma;
1108     }                                            1108     }
1109                                                  1109 
1110                                                  1110 
1111     G4double CrossSectionsMultiPionsAndResona    1111     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaOnePi(Particle const * const particle1, Particle const * const particle2) {
1112         // Cross section for nucleon-nucleon     1112         // Cross section for nucleon-nucleon producing one omega and one pion
1113                                                  1113 
1114         const G4int iso=ParticleTable::getIso    1114         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1115         if (iso!=0)                              1115         if (iso!=0)
1116             return 0.;                           1116             return 0.;
1117                                                  1117 
1118         const G4double ener=KinematicsUtils::    1118         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega (= 2802. - 2018.563; 4074595.287720512986=2018.563*2018.563)
1119         if (ener < 2018.563) return 0.;          1119         if (ener < 2018.563) return 0.;
1120                                                  1120 
1121         const G4double xsiso2=CrossSectionsMu    1121         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1122         const G4double xsiso0=CrossSectionsMu    1122         const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
1123                                                  1123 
1124         return 0.25*(CrossSectionsMultiPions:    1124         return 0.25*(CrossSectionsMultiPions::NNOnePiOrDelta(ener, 0, xsiso0)+ CrossSectionsMultiPions::NNOnePiOrDelta(ener, 2, xsiso2));
1125     }                                            1125     }
1126                                                  1126 
1127     G4double CrossSectionsMultiPionsAndResona    1127     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaOnePiOrDelta(Particle const * const particle1, Particle const * const particle2) {
1128         const G4double ener=KinematicsUtils::    1128         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega
1129         if (ener < 2018.563) return 0.;          1129         if (ener < 2018.563) return 0.;
1130         const G4int iso=ParticleTable::getIso    1130         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1131                                                  1131 
1132         const G4double xsiso2=CrossSectionsMu    1132         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1133         if (iso != 0)                            1133         if (iso != 0)
1134             return CrossSectionsMultiPions::N    1134             return CrossSectionsMultiPions::NNOnePiOrDelta(ener, iso, xsiso2);
1135         else {                                   1135         else {
1136             const G4double xsiso0=CrossSectio    1136             const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
1137             return 0.5*(CrossSectionsMultiPio    1137             return 0.5*(CrossSectionsMultiPions::NNOnePiOrDelta(ener, 0, xsiso0)+ CrossSectionsMultiPions::NNOnePiOrDelta(ener, 2, xsiso2));
1138         }                                        1138         }
1139     }                                            1139     }
1140                                                  1140 
1141     G4double CrossSectionsMultiPionsAndResona    1141     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaTwoPi(Particle const * const particle1, Particle const * const particle2) {
1142         //                                       1142         //
1143         //     Nucleon-Nucleon producing one     1143         //     Nucleon-Nucleon producing one omega and two pions 
1144         //                                       1144         //
1145         const G4double ener=KinematicsUtils::    1145         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega
1146         if (ener < 2018.563) return 0.;          1146         if (ener < 2018.563) return 0.;
1147         const G4int iso=ParticleTable::getIso    1147         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1148                                                  1148 
1149         const G4double xsiso2=CrossSectionsMu    1149         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1150         if (iso != 0) {                          1150         if (iso != 0) {
1151             return CrossSectionsMultiPions::N    1151             return CrossSectionsMultiPions::NNTwoPi(ener, 2, xsiso2);
1152         }                                        1152         }
1153         else {                                   1153         else {
1154             const G4double xsiso0=CrossSectio    1154             const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
1155             return 0.5*(CrossSectionsMultiPio    1155             return 0.5*(CrossSectionsMultiPions::NNTwoPi(ener, 0, xsiso0)+ CrossSectionsMultiPions::NNTwoPi(ener, 2, xsiso2));
1156         }                                        1156         }
1157     }                                            1157     }
1158                                                  1158 
1159     G4double CrossSectionsMultiPionsAndResona    1159     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaThreePi(Particle const * const particle1, Particle const * const particle2) {
1160         //                                       1160         //
1161         //     Nucleon-Nucleon producing one     1161         //     Nucleon-Nucleon producing one omega and three pions
1162         //                                       1162         //
1163                                                  1163 
1164         const G4double ener=KinematicsUtils::    1164         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega
1165         if (ener < 2018.563) return 0.;          1165         if (ener < 2018.563) return 0.;
1166         const G4int iso=ParticleTable::getIso    1166         const G4int iso=ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1167                                                  1167 
1168                                                  1168 
1169         const G4double xsiso2=CrossSectionsMu    1169         const G4double xsiso2=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1170         const G4double xs1pi2=CrossSectionsMu    1170         const G4double xs1pi2=CrossSectionsMultiPions::NNOnePiOrDelta(ener, 2, xsiso2);
1171         const G4double xs2pi2=CrossSectionsMu    1171         const G4double xs2pi2=CrossSectionsMultiPions::NNTwoPi(ener, 2, xsiso2);
1172         if (iso != 0)                            1172         if (iso != 0)
1173             return CrossSectionsMultiPions::N    1173             return CrossSectionsMultiPions::NNThreePi(ener, 2, xsiso2, xs1pi2, xs2pi2);
1174         else {                                   1174         else {
1175             const G4double xsiso0=CrossSectio    1175             const G4double xsiso0=CrossSectionsMultiPions::NNInelasticIso(ener, 0);
1176             const G4double xs1pi0=CrossSectio    1176             const G4double xs1pi0=CrossSectionsMultiPions::NNOnePiOrDelta(ener, 0, xsiso0);
1177             const G4double xs2pi0=CrossSectio    1177             const G4double xs2pi0=CrossSectionsMultiPions::NNTwoPi(ener, 0, xsiso0);
1178             return 0.5*(CrossSectionsMultiPio    1178             return 0.5*(CrossSectionsMultiPions::NNThreePi(ener, 0, xsiso0, xs1pi0, xs2pi0)+ CrossSectionsMultiPions::NNThreePi(ener, 2, xsiso2, xs1pi2, xs2pi2));
1179         }                                        1179         }
1180     }                                            1180     }
1181                                                  1181 
1182     G4double CrossSectionsMultiPionsAndResona    1182     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaFourPi(Particle const * const particle1, Particle const * const particle2) {
1183         //                                       1183         //
1184         //     Nucleon-Nucleon producing one     1184         //     Nucleon-Nucleon producing one omega and four pions
1185         //                                       1185         //
1186 //jcd to be removed                              1186 //jcd to be removed
1187 //        return 0.;                             1187 //        return 0.;
1188 //jcd                                            1188 //jcd    
1189                                                  1189 
1190         const G4double ener=KinematicsUtils::    1190         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega
1191         if (ener < 2018.563) return 0.;          1191         if (ener < 2018.563) return 0.;
1192         const G4double s = ener*ener;            1192         const G4double s = ener*ener;
1193         const G4int i = ParticleTable::getIso    1193         const G4int i = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1194         G4double xsinelas;                       1194         G4double xsinelas;
1195         if (i!=0)                                1195         if (i!=0) 
1196             xsinelas=CrossSectionsMultiPions:    1196             xsinelas=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1197         else                                     1197         else 
1198             xsinelas=0.5*(CrossSectionsMultiP    1198             xsinelas=0.5*(CrossSectionsMultiPions::NNInelasticIso(ener, 0)+CrossSectionsMultiPions::NNInelasticIso(ener, 2));
1199         if (xsinelas <= 1.e-9) return 0.;        1199         if (xsinelas <= 1.e-9) return 0.;
1200         G4double ratio=(NNToNNOmega(particle1    1200         G4double ratio=(NNToNNOmega(particle1, particle2)-NNToNNOmegaExclu(particle1, particle2))/xsinelas;
1201         if(s<6.25E6)                             1201         if(s<6.25E6)
1202             return 0.;                           1202             return 0.;
1203         const G4double sigma = NNToNNOmega(pa    1203         const G4double sigma = NNToNNOmega(particle1, particle2) - NNToNNOmegaExclu(particle1, particle2) - ratio*(NNToNNOmegaOnePiOrDelta(particle1, particle2) + NNToNNOmegaTwoPi(particle1, particle2) + NNToNNOmegaThreePi(particle1, particle2));
1204         return ((sigma>1.e-9) ? sigma : 0.);     1204         return ((sigma>1.e-9) ? sigma : 0.);
1205     }                                            1205     }
1206                                                  1206 
1207     G4double CrossSectionsMultiPionsAndResona    1207     G4double CrossSectionsMultiPionsAndResonances::NNToNNOmegaxPi(const G4int xpi, Particle const * const particle1, Particle const * const particle2) {
1208         //                                       1208         //
1209         //     Nucleon-Nucleon producing one     1209         //     Nucleon-Nucleon producing one omega and xpi pions
1210         //                                       1210         //
1211 // assert(xpi>0 && xpi<=nMaxPiNN);               1211 // assert(xpi>0 && xpi<=nMaxPiNN);
1212 // assert(particle1->isNucleon() && particle2    1212 // assert(particle1->isNucleon() && particle2->isNucleon());
1213 //jcd to be removed                              1213 //jcd to be removed
1214 //        return 0.;                             1214 //        return 0.;
1215 //jcd                                            1215 //jcd    
1216                                                  1216 
1217         const G4double ener=KinematicsUtils::    1217         const G4double ener=KinematicsUtils::totalEnergyInCM(particle1, particle2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega
1218         if (ener < 2018.563) return 0.;          1218         if (ener < 2018.563) return 0.;
1219         const G4int i = ParticleTable::getIso    1219         const G4int i = ParticleTable::getIsospin(particle1->getType()) + ParticleTable::getIsospin(particle2->getType());
1220         G4double xsinelas;                       1220         G4double xsinelas;
1221         if (i!=0)                                1221         if (i!=0) 
1222             xsinelas=CrossSectionsMultiPions:    1222             xsinelas=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1223         else                                     1223         else 
1224             xsinelas=0.5*(CrossSectionsMultiP    1224             xsinelas=0.5*(CrossSectionsMultiPions::NNInelasticIso(ener, 0)+CrossSectionsMultiPions::NNInelasticIso(ener, 2));
1225         if (xsinelas <= 1.e-9) return 0.;        1225         if (xsinelas <= 1.e-9) return 0.;
1226         G4double ratio=(NNToNNOmega(particle1    1226         G4double ratio=(NNToNNOmega(particle1, particle2)-NNToNNOmegaExclu(particle1, particle2))/xsinelas;
1227                                                  1227 
1228         if (xpi == 1)                            1228         if (xpi == 1)
1229             return NNToNNOmegaOnePi(particle1    1229             return NNToNNOmegaOnePi(particle1, particle2)*ratio;
1230         else if (xpi == 2)                       1230         else if (xpi == 2)
1231             return NNToNNOmegaTwoPi(particle1    1231             return NNToNNOmegaTwoPi(particle1, particle2)*ratio;
1232         else if (xpi == 3)                       1232         else if (xpi == 3)
1233             return NNToNNOmegaThreePi(particl    1233             return NNToNNOmegaThreePi(particle1, particle2)*ratio;
1234         else if (xpi == 4)                       1234         else if (xpi == 4)
1235             return NNToNNOmegaFourPi(particle    1235             return NNToNNOmegaFourPi(particle1, particle2);
1236         else // should never reach this point    1236         else // should never reach this point
1237             return 0.;                           1237             return 0.;
1238     }                                            1238     }
1239                                                  1239 
1240                                                  1240 
1241     G4double CrossSectionsMultiPionsAndResona    1241     G4double CrossSectionsMultiPionsAndResonances::NNToNDeltaOmega(Particle const * const p1, Particle const * const p2) {
1242 // assert(p1->isNucleon() && p2->isNucleon())    1242 // assert(p1->isNucleon() && p2->isNucleon());
1243 //jcd to be removed                              1243 //jcd to be removed
1244 //        return 0.;                             1244 //        return 0.;
1245 //jcd                                            1245 //jcd    
1246         const G4int i = ParticleTable::getIso    1246         const G4int i = ParticleTable::getIsospin(p1->getType()) + ParticleTable::getIsospin(p2->getType());
1247         const G4double ener=KinematicsUtils::    1247         const G4double ener=KinematicsUtils::totalEnergyInCM(p1, p2) - 783.437; // 783.437 MeV translation to open pion production in NNOmega
1248         if (ener < 2018.563) return 0.;          1248         if (ener < 2018.563) return 0.;
1249         G4double xsinelas;                       1249         G4double xsinelas;
1250         if (i!=0)                                1250         if (i!=0) 
1251             xsinelas=CrossSectionsMultiPions:    1251             xsinelas=CrossSectionsMultiPions::NNInelasticIso(ener, 2);
1252         else                                     1252         else 
1253             xsinelas=0.5*(CrossSectionsMultiP    1253             xsinelas=0.5*(CrossSectionsMultiPions::NNInelasticIso(ener, 0)+CrossSectionsMultiPions::NNInelasticIso(ener, 2));
1254         if (xsinelas <= 1.e-9) return 0.;        1254         if (xsinelas <= 1.e-9) return 0.;
1255         G4double ratio=(NNToNNOmega(p1, p2)-N    1255         G4double ratio=(NNToNNOmega(p1, p2)-NNToNNOmegaExclu(p1, p2))/xsinelas;
1256         G4double sigma = NNToNNOmegaOnePiOrDe    1256         G4double sigma = NNToNNOmegaOnePiOrDelta(p1, p2)*ratio;
1257         if(i==0)                                 1257         if(i==0)
1258             sigma *= 0.5;                        1258             sigma *= 0.5;
1259         return sigma;                            1259         return sigma;
1260     }                                            1260     }
1261                                                  1261 
1262                                                  1262 
1263 } // namespace G4INCL                            1263 } // namespace G4INCL
1264                                                  1264 
1265                                                  1265