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Geant4/processes/hadronic/cross_sections/src/G4HadronNucleonXsc.cc

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Differences between /processes/hadronic/cross_sections/src/G4HadronNucleonXsc.cc (Version 11.3.0) and /processes/hadronic/cross_sections/src/G4HadronNucleonXsc.cc (Version 11.0.p1)


  1 //                                                  1 //
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 25 //                                                 25 //
 26 // 14.03.07 V. Grichine - first implementation     26 // 14.03.07 V. Grichine - first implementation
 27 //                                                 27 //
 28 // 04.09.18 V. Ivantchenko Major revision of i     28 // 04.09.18 V. Ivantchenko Major revision of interfaces and implementation
 29 // 30.09.18 V. Grichine hyperon-nucleon xsc fi     29 // 30.09.18 V. Grichine hyperon-nucleon xsc first implementation
 30                                                    30 
 31 #include "G4HadronNucleonXsc.hh"                   31 #include "G4HadronNucleonXsc.hh"
 32 #include "G4Element.hh"                            32 #include "G4Element.hh"
 33 #include "G4Proton.hh"                             33 #include "G4Proton.hh"
 34 #include "G4Nucleus.hh"                            34 #include "G4Nucleus.hh"
 35 #include "G4PhysicalConstants.hh"                  35 #include "G4PhysicalConstants.hh"
 36 #include "G4SystemOfUnits.hh"                      36 #include "G4SystemOfUnits.hh"
 37 #include "G4ParticleTable.hh"                      37 #include "G4ParticleTable.hh"
 38 #include "G4IonTable.hh"                           38 #include "G4IonTable.hh"
 39 #include "G4HadTmpUtil.hh"                         39 #include "G4HadTmpUtil.hh"
 40 #include "G4Log.hh"                                40 #include "G4Log.hh"
 41 #include "G4Exp.hh"                                41 #include "G4Exp.hh"
 42 #include "G4Pow.hh"                                42 #include "G4Pow.hh"
 43 #include "G4NuclearRadii.hh"                       43 #include "G4NuclearRadii.hh"
 44                                                    44 
 45 #include "G4Neutron.hh"                            45 #include "G4Neutron.hh"
 46 #include "G4PionPlus.hh"                           46 #include "G4PionPlus.hh"
 47 #include "G4KaonPlus.hh"                           47 #include "G4KaonPlus.hh"
 48 #include "G4KaonMinus.hh"                          48 #include "G4KaonMinus.hh"
 49 #include "G4KaonZeroShort.hh"                      49 #include "G4KaonZeroShort.hh"
 50 #include "G4KaonZeroLong.hh"                       50 #include "G4KaonZeroLong.hh"
 51                                                    51 
 52 namespace                                      <<  52 static const G4double invGeV  = 1.0/CLHEP::GeV;
 53 {                                              <<  53 static const G4double invGeV2 = 1.0/(CLHEP::GeV*CLHEP::GeV);
 54   const G4double invGeV  = 1.0/CLHEP::GeV;     <<  54 // PDG fit constants
 55   const G4double invGeV2 = 1.0/(CLHEP::GeV*CLH <<  55 static const G4double minLogP = 3.5;    // min of (lnP-minLogP)^2 
 56   // PDG fit constants                         <<  56 static const G4double cofLogE = .0557;  // elastic (lnP-minLogP)^2 
 57   const G4double minLogP = 3.5;    // min of ( <<  57 static const G4double cofLogT = .3;     // total (lnP-minLogP)^2 
 58   const G4double cofLogE = .0557;  // elastic  <<  58 static const G4double pMin = .1;        // fast LE calculation 
 59   const G4double cofLogT = .3;     // total (l <<  59 static const G4double pMax = 1000.;     // fast HE calculation 
 60   const G4double pMin = .1;        // fast LE  <<  60 static const G4double ekinmin = 0.1*CLHEP::MeV;   // protection against zero ekin 
 61   const G4double pMax = 1000.;     // fast HE  <<  61 static const G4double ekinmaxQB = 100*CLHEP::MeV; // max kinetic energy for Coulomb barrier  
 62   const G4double ekinmin = 0.1*CLHEP::MeV;   / << 
 63   const G4double ekinmaxQB = 100*CLHEP::MeV; / << 
 64 }                                              << 
 65                                                    62 
 66 G4HadronNucleonXsc::G4HadronNucleonXsc()           63 G4HadronNucleonXsc::G4HadronNucleonXsc() 
                                                   >>  64   : fTotalXsc(0.0), fElasticXsc(0.0), fInelasticXsc(0.0)
 67 {                                                  65 {
 68   // basic hadrons                             << 
 69   theProton   = G4Proton::Proton();                66   theProton   = G4Proton::Proton();
 70   theNeutron  = G4Neutron::Neutron();              67   theNeutron  = G4Neutron::Neutron();
 71   thePiPlus   = G4PionPlus::PionPlus();            68   thePiPlus   = G4PionPlus::PionPlus();
 72                                                    69 
 73   // basic strange mesons                      <<  70   // strange
 74   theKPlus    = G4KaonPlus::KaonPlus();            71   theKPlus    = G4KaonPlus::KaonPlus();
 75   theKMinus   = G4KaonMinus::KaonMinus();          72   theKMinus   = G4KaonMinus::KaonMinus();
 76   theK0S      = G4KaonZeroShort::KaonZeroShort     73   theK0S      = G4KaonZeroShort::KaonZeroShort();
 77   theK0L      = G4KaonZeroLong::KaonZeroLong()     74   theK0L      = G4KaonZeroLong::KaonZeroLong();
 78                                                    75 
 79   g4calc = G4Pow::GetInstance();                   76   g4calc = G4Pow::GetInstance();
 80 }                                                  77 }
 81                                                    78 
                                                   >>  79 G4HadronNucleonXsc::~G4HadronNucleonXsc()
                                                   >>  80 {}
                                                   >>  81 
 82 void G4HadronNucleonXsc::CrossSectionDescripti     82 void G4HadronNucleonXsc::CrossSectionDescription(std::ostream& outFile) const
 83 {                                                  83 {
 84   outFile << "G4HadronNucleonXsc calculates th     84   outFile << "G4HadronNucleonXsc calculates the total, inelastic and elastic\n"
 85           << "hadron-nucleon cross sections us     85           << "hadron-nucleon cross sections using several different\n"
 86           << "parameterizations within the Gla     86           << "parameterizations within the Glauber-Gribov approach. It is\n"
 87           << "valid for all incident gammas an     87           << "valid for all incident gammas and long-lived hadrons at\n"
 88           << "energies above 30 keV.  This is      88           << "energies above 30 keV.  This is a cross section component which\n"
 89           << "is to be used to build a cross s     89           << "is to be used to build a cross section data set.\n"; 
 90 }                                                  90 }
 91                                                    91 
 92 G4double G4HadronNucleonXsc::HadronNucleonXsc(     92 G4double G4HadronNucleonXsc::HadronNucleonXsc(  const G4ParticleDefinition* theParticle,
 93                                const G4Particl     93                                const G4ParticleDefinition* nucleon, G4double ekin)
 94 {                                                  94 {
 95   G4double xsc(0.);                                95   G4double xsc(0.);
 96   G4int pdg = std::abs(theParticle->GetPDGEnco     96   G4int pdg = std::abs(theParticle->GetPDGEncoding());
 97                                                    97   
 98   // p, n, pi+-, pbar, nbar                        98   // p, n, pi+-, pbar, nbar
 99   if ( pdg == 2212 || pdg == 2112 || pdg == 21     99   if ( pdg == 2212 || pdg == 2112 || pdg == 211 ) { 
100     xsc = HadronNucleonXscNS(theParticle, nucl    100     xsc = HadronNucleonXscNS(theParticle, nucleon, ekin);
101   }                                               101   }
102   else if ( pdg == 22 ) // gamma                  102   else if ( pdg == 22 ) // gamma
103   {                                               103   {
104     xsc = HadronNucleonXscPDG(theParticle, nuc    104     xsc = HadronNucleonXscPDG(theParticle, nucleon, ekin);
105   }                                               105   }
106   else if ( pdg == 321 || pdg == 310 || pdg ==    106   else if ( pdg == 321 || pdg == 310 || pdg == 130 ) // K+-, K0L, K0S
107   {                                               107   {
108     xsc = KaonNucleonXscNS(theParticle, nucleo    108     xsc = KaonNucleonXscNS(theParticle, nucleon, ekin);
109   }                                               109   }
110   else if (pdg > 3000)                            110   else if (pdg > 3000) 
111   {                                               111   {
112     if (pdg == 3122 || pdg == 3222 || pdg == 3    112     if (pdg == 3122 || pdg == 3222 || pdg == 3112 || pdg == 3212 || pdg == 3322 || pdg == 3312 || pdg == 3324 ||
113   pdg == 4122 || pdg == 4332 || pdg == 4122 ||    113   pdg == 4122 || pdg == 4332 || pdg == 4122 || pdg == 4212 || pdg == 4222 || pdg == 4112 || pdg == 4232 || pdg == 4132 ||
114         pdg == 5122 || pdg == 5332 || pdg == 5    114         pdg == 5122 || pdg == 5332 || pdg == 5122 || pdg == 5112 || pdg == 5222 || pdg == 5212 || pdg == 5132 || pdg == 5232
115        ) // heavy s-,c-,b-hyperons                115        ) // heavy s-,c-,b-hyperons
116     {                                             116     {
117       xsc = HyperonNucleonXscNS(theParticle, n    117       xsc = HyperonNucleonXscNS(theParticle, nucleon, ekin);
118     }                                             118     }
119     else                                          119     else 
120     {                                             120     {
121       xsc = HadronNucleonXscPDG(theParticle, n    121       xsc = HadronNucleonXscPDG(theParticle, nucleon, ekin);
122     }                                             122     }
123   } else if (pdg > 220) {                         123   } else if (pdg > 220) {
124     if (pdg == 511 || pdg == 421 || pdg == 531    124     if (pdg == 511 || pdg == 421 || pdg == 531 || pdg == 541 || pdg == 431 || pdg == 411 || pdg == 521 ||
125   pdg == 221 || pdg == 331 || pdg == 441 || pd    125   pdg == 221 || pdg == 331 || pdg == 441 || pdg == 443 || pdg == 543) // s-,c-,b-mesons
126     {                                             126     {
127       xsc = SCBMesonNucleonXscNS(theParticle,     127       xsc = SCBMesonNucleonXscNS(theParticle, nucleon, ekin);
128     }                                             128     }
129     else                                          129     else 
130     {                                             130     {
131       xsc = HadronNucleonXscPDG(theParticle, n    131       xsc = HadronNucleonXscPDG(theParticle, nucleon, ekin);
132     }                                             132     }
133   } else {                                        133   } else {
134     xsc = HadronNucleonXscPDG(theParticle, nuc    134     xsc = HadronNucleonXscPDG(theParticle, nucleon, ekin);
135   }                                               135   }
136   return xsc;                                     136   return xsc;
137 }                                                 137 }
138                                                   138 
139 //////////////////////////////////////////////    139 //////////////////////////////////////////////////////////////////////////////
140 //                                                140 //
141 // Returns hadron-nucleon Xsc according to PDG    141 // Returns hadron-nucleon Xsc according to PDG parametrisation (2017):
142 // http://pdg.lbl.gov/2017/reviews/hadronicrpp    142 // http://pdg.lbl.gov/2017/reviews/hadronicrpp.pdf
143                                                   143 
144 G4double G4HadronNucleonXsc::HadronNucleonXscP    144 G4double G4HadronNucleonXsc::HadronNucleonXscPDG(
145                              const G4ParticleD    145                              const G4ParticleDefinition* theParticle, 
146            const G4ParticleDefinition* nucleon    146            const G4ParticleDefinition* nucleon, G4double ekin)
147 {                                                 147 {
148   static const G4double M    = 2.1206; // in G    148   static const G4double M    = 2.1206; // in Gev
149   static const G4double eta1 = 0.4473;            149   static const G4double eta1 = 0.4473;
150   static const G4double eta2 = 0.5486;            150   static const G4double eta2 = 0.5486;
151   static const G4double H    = 0.272;             151   static const G4double H    = 0.272;
152                                                   152 
153   G4int pdg = theParticle->GetPDGEncoding();      153   G4int pdg = theParticle->GetPDGEncoding();
154                                                   154 
155   G4double mass1 = (pdg == 22) ? 770. : thePar    155   G4double mass1 = (pdg == 22) ? 770. : theParticle->GetPDGMass();
156   G4double mass2 = nucleon->GetPDGMass();         156   G4double mass2 = nucleon->GetPDGMass();
157                                                   157 
158   G4double sMand = CalcMandelstamS(ekin, mass1    158   G4double sMand = CalcMandelstamS(ekin, mass1, mass2)*invGeV2;
159   G4double x = (mass1 + mass2)*invGeV + M;        159   G4double x = (mass1 + mass2)*invGeV + M;
160   G4double blog = G4Log(sMand/(x*x));             160   G4double blog = G4Log(sMand/(x*x));
161                                                   161 
162   G4double P(0.0), R1(0.0), R2(0.0), del(1.0);    162   G4double P(0.0), R1(0.0), R2(0.0), del(1.0);
163                                                   163 
164   G4bool proton  = (nucleon == theProton);        164   G4bool proton  = (nucleon == theProton);
165   G4bool neutron = (nucleon == theNeutron);       165   G4bool neutron = (nucleon == theNeutron);
166                                                   166   
167   if(theParticle == theNeutron)                   167   if(theParticle == theNeutron)
168   {                                               168   {
169     if ( proton )                                 169     if ( proton )
170     {                                             170     {
171       P  = 34.71;                                 171       P  = 34.71;
172       R1 = 12.52;                                 172       R1 = 12.52;
173       R2 = -6.66;                                 173       R2 = -6.66;
174     }                                             174     }
175     else                                          175     else
176     {                                             176     {
177       P  = 34.41;                                 177       P  = 34.41;
178       R1 = 13.07;                                 178       R1 = 13.07;
179       R2 = -7.394;                                179       R2 = -7.394;
180     }                                             180     }
181   }                                               181   } 
182   else if(theParticle == theProton)               182   else if(theParticle == theProton) 
183   {                                               183   {
184     if ( neutron )                                184     if ( neutron )
185     {                                             185     {
186       P  = 34.71;                                 186       P  = 34.71;
187       R1 = 12.52;                                 187       R1 = 12.52;
188       R2 = -6.66;                                 188       R2 = -6.66;
189     }                                             189     }
190     else                                          190     else
191     {                                             191     {
192       P  = 34.41;                                 192       P  = 34.41;
193       R1 = 13.07;                                 193       R1 = 13.07;
194       R2 = -7.394;                                194       R2 = -7.394;
195     }                                             195     }
196   }                                               196   } 
197   // pbar                                         197   // pbar
198   else if(pdg == -2212)                           198   else if(pdg == -2212) 
199   {                                               199   {
200     if ( neutron )                                200     if ( neutron )
201     {                                             201     {
202       P  = 34.71;                                 202       P  = 34.71;
203       R1 = 12.52;                                 203       R1 = 12.52;
204       R2 = 6.66;                                  204       R2 = 6.66;
205     }                                             205     }
206     else                                          206     else
207     {                                             207     {
208       P  = 34.41;                                 208       P  = 34.41;
209       R1 = 13.07;                                 209       R1 = 13.07;
210       R2 = 7.394;                                 210       R2 = 7.394;
211     }                                             211     }
212   }                                               212   } 
213   // nbar                                         213   // nbar
214   else if(pdg == -2112)                           214   else if(pdg == -2112) 
215   {                                               215   {
216     if ( proton )                                 216     if ( proton )
217     {                                             217     {
218       P  = 34.71;                                 218       P  = 34.71;
219       R1 = 12.52;                                 219       R1 = 12.52;
220       R2 = 6.66;                                  220       R2 = 6.66;
221     }                                             221     }
222     else                                          222     else
223     {                                             223     {
224       P  = 34.41;                                 224       P  = 34.41;
225       R1 = 13.07;                                 225       R1 = 13.07;
226       R2 = 7.394;                                 226       R2 = 7.394;
227     }                                             227     }
228   }                                               228   } 
229   // pi+                                          229   // pi+
230   else if(pdg == 211)                             230   else if(pdg == 211) 
231   {                                               231   {
232     P  = 18.75;                                   232     P  = 18.75;
233     R1 = 9.56;                                    233     R1 = 9.56;
234     R2 = -1.767;                                  234     R2 = -1.767;
235   }                                               235   } 
236   // pi-                                          236   // pi-
237   else if(pdg == -211)                            237   else if(pdg == -211) 
238   {                                               238   {
239     P  = 18.75;                                   239     P  = 18.75;
240     R1 = 9.56;                                    240     R1 = 9.56;
241     R2 = 1.767;                                   241     R2 = 1.767;
242   }                                               242   } 
243   else if(theParticle == theKPlus)                243   else if(theParticle == theKPlus) 
244   {                                               244   {
245     if ( proton )                                 245     if ( proton )
246     {                                             246     {
247       P  = 16.36;                                 247       P  = 16.36;
248       R1 = 4.29;                                  248       R1 = 4.29;
249       R2 = -3.408;                                249       R2 = -3.408;
250     }                                             250     }
251     else                                          251     else
252     {                                             252     {
253       P  = 16.31;                                 253       P  = 16.31;
254       R1 = 3.7;                                   254       R1 = 3.7;
255       R2 = -1.826;                                255       R2 = -1.826;
256     }                                             256     }
257   }                                               257   } 
258   else if(theParticle == theKMinus)               258   else if(theParticle == theKMinus) 
259   {                                               259   {
260     if ( proton )                                 260     if ( proton )
261     {                                             261     {
262       P  = 16.36;                                 262       P  = 16.36;
263       R1 = 4.29;                                  263       R1 = 4.29;
264       R2 = 3.408;                                 264       R2 = 3.408;
265     }                                             265     }
266     else                                          266     else
267     {                                             267     {
268       P  = 16.31;                                 268       P  = 16.31;
269       R1 = 3.7;                                   269       R1 = 3.7;
270       R2 = 1.826;                                 270       R2 = 1.826;
271     }                                             271     }
272   }                                               272   }
273   else if(theParticle == theK0S || theParticle    273   else if(theParticle == theK0S || theParticle == theK0L) 
274   {                                               274   {
275     P  = 16.36;                                   275     P  = 16.36;
276     R1 = 2.5;                                     276     R1 = 2.5;
277     R2 = 0.;                                      277     R2 = 0.;
278   }                                               278   }
279   // sigma-                                       279   // sigma-
280   else if(pdg == 3112)                            280   else if(pdg == 3112) 
281   {                                               281   {
282     P  = 34.7;                                    282     P  = 34.7;
283     R1 = -46.;                                    283     R1 = -46.;
284     R2 = 48.;                                     284     R2 = 48.;
285   }                                               285   } 
286   // gamma                                        286   // gamma
287   else if(pdg == 22) // modify later on           287   else if(pdg == 22) // modify later on
288   {                                               288   {
289     del= 0.003063;                                289     del= 0.003063;
290     P  = 34.71*del;                               290     P  = 34.71*del;
291     R1 = (neutron) ? 0.0231 : 0.0139;             291     R1 = (neutron) ? 0.0231 : 0.0139;
292     R2 = 0.;                                      292     R2 = 0.;
293   }                                               293   } 
294   else  // as proton ???                          294   else  // as proton ??? 
295   {                                               295   {
296     if ( neutron )                                296     if ( neutron )
297     {                                             297     {
298       P  = 34.71;                                 298       P  = 34.71;
299       R1 = 12.52;                                 299       R1 = 12.52;
300       R2 = -6.66;                                 300       R2 = -6.66;
301     }                                             301     }
302     else                                          302     else
303     {                                             303     {
304       P  = 34.41;                                 304       P  = 34.41;
305       R1 = 13.07;                                 305       R1 = 13.07;
306       R2 = -7.394;                                306       R2 = -7.394;
307     }                                             307     }
308   }                                               308   } 
309   fTotalXsc = CLHEP::millibarn*                   309   fTotalXsc = CLHEP::millibarn* 
310     (del*(H*blog*blog + P) + R1*G4Exp(-eta1*bl    310     (del*(H*blog*blog + P) + R1*G4Exp(-eta1*blog) + R2*G4Exp(-eta2*blog));
311   fInelasticXsc = 0.75*fTotalXsc;                 311   fInelasticXsc = 0.75*fTotalXsc;
312   fElasticXsc   = fTotalXsc - fInelasticXsc;      312   fElasticXsc   = fTotalXsc - fInelasticXsc;
313                                                   313 
314   if( proton && theParticle->GetPDGCharge() >     314   if( proton && theParticle->GetPDGCharge() > 0. && ekin < ekinmaxQB )
315   {                                               315   {
316     G4double cB = CoulombBarrier(theParticle,     316     G4double cB = CoulombBarrier(theParticle, nucleon, ekin);
317     fTotalXsc   *= cB;                            317     fTotalXsc   *= cB;
318     fElasticXsc *= cB;                            318     fElasticXsc *= cB; 
319     fInelasticXsc *= cB;                          319     fInelasticXsc *= cB; 
320   }                                               320   }
321   /*                                              321   /*
322   G4cout << "## HadronNucleonXscPDG: ekin(MeV)    322   G4cout << "## HadronNucleonXscPDG: ekin(MeV)= " << ekin 
323    << " tot= " << fTotalXsc/CLHEP::millibarn      323    << " tot= " << fTotalXsc/CLHEP::millibarn 
324    << " inel= " << fInelasticXsc/CLHEP::millib    324    << " inel= " << fInelasticXsc/CLHEP::millibarn
325    << " el= " << fElasticXsc/CLHEP::millibarn     325    << " el= " << fElasticXsc/CLHEP::millibarn
326          << G4endl;                               326          << G4endl;
327   */                                              327   */
328   return fTotalXsc;                               328   return fTotalXsc;
329 }                                                 329 }
330                                                   330 
331 //////////////////////////////////////////////    331 //////////////////////////////////////////////////////////////////////////////
332 //                                                332 //
333 // Returns hadron-nucleon cross-section based     333 // Returns hadron-nucleon cross-section based on N. Starkov parametrisation of
334 // data from mainly http://wwwppds.ihep.su:800    334 // data from mainly http://wwwppds.ihep.su:8001/c5-6A.html database
335                                                   335 
336 G4double G4HadronNucleonXsc::HadronNucleonXscN    336 G4double G4HadronNucleonXsc::HadronNucleonXscNS(
337                              const G4ParticleD    337                              const G4ParticleDefinition* theParticle, 
338            const G4ParticleDefinition* nucleon    338            const G4ParticleDefinition* nucleon, G4double ekin0)
339 {                                                 339 {  
340   const G4double ekin = std::max(ekin0, ekinmi    340   const G4double ekin = std::max(ekin0, ekinmin);
341   G4int pdg = theParticle->GetPDGEncoding();      341   G4int pdg = theParticle->GetPDGEncoding();
342   /*                                              342   /*  
343   G4cout<< "HadronNucleonXscNS: Ekin(GeV)= " <    343   G4cout<< "HadronNucleonXscNS: Ekin(GeV)= " << ekin/GeV << "  "
344         << theParticle->GetParticleName() << "    344         << theParticle->GetParticleName() << " + " 
345         << nucleon->GetParticleName() << G4end    345         << nucleon->GetParticleName() << G4endl;
346   */                                              346   */
347   if(pdg == -2212 || pdg == -2112) {              347   if(pdg == -2212 || pdg == -2112) {
348     return HadronNucleonXscPDG(theParticle, nu    348     return HadronNucleonXscPDG(theParticle, nucleon, ekin);
349   }                                               349   }
350                                                   350 
351   G4double pM   = theParticle->GetPDGMass();      351   G4double pM   = theParticle->GetPDGMass();
352   G4double tM   = nucleon->GetPDGMass();          352   G4double tM   = nucleon->GetPDGMass();
353   G4double pE   = ekin + pM;                      353   G4double pE   = ekin + pM; 
354   G4double pLab = std::sqrt(ekin*(ekin + 2*pM)    354   G4double pLab = std::sqrt(ekin*(ekin + 2*pM));
355                                                   355 
356   G4double sMand = CalcMandelstamS(ekin, pM, t    356   G4double sMand = CalcMandelstamS(ekin, pM, tM)*invGeV2;
357                                                   357 
358   pLab *= invGeV;                                 358   pLab *= invGeV;
359   pE   *= invGeV;                                 359   pE   *= invGeV;
360                                                   360 
361   if(pLab >= 10.) {                               361   if(pLab >= 10.) {
362     fTotalXsc = HadronNucleonXscPDG(theParticl    362     fTotalXsc = HadronNucleonXscPDG(theParticle, nucleon, ekin)/CLHEP::millibarn;
363   } else { fTotalXsc = 0.0; }                     363   } else { fTotalXsc = 0.0; }
364   fElasticXsc = 0.0;                              364   fElasticXsc = 0.0;
365   //G4cout << "Stot(mb)= " << fTotalXsc << " p    365   //G4cout << "Stot(mb)= " << fTotalXsc << " pLab= " << pLab 
366   //   << " Smand= " << sMand <<G4endl;           366   //   << " Smand= " << sMand <<G4endl;
367   G4double logP = G4Log(pLab);                    367   G4double logP = G4Log(pLab);
368                                                   368 
369   G4bool proton = (nucleon == theProton);         369   G4bool proton = (nucleon == theProton);
370   G4bool neutron = (nucleon == theNeutron);       370   G4bool neutron = (nucleon == theNeutron);
371                                                   371 
372   if( theParticle == theNeutron)                  372   if( theParticle == theNeutron) 
373   {                                               373   {
374     if( pLab >= 373.)                             374     if( pLab >= 373.)
375     {                                             375     {
376       fElasticXsc = 6.5 + 0.308*G4Exp(G4Log(G4    376       fElasticXsc = 6.5 + 0.308*G4Exp(G4Log(G4Log(sMand/400.)*1.65)) 
377   + 9.19*G4Exp(-G4Log(sMand)*0.458);              377   + 9.19*G4Exp(-G4Log(sMand)*0.458);
378     }                                             378     }
379     else if( pLab >= 100.)                        379     else if( pLab >= 100.)
380     {                                             380     {
381       fElasticXsc = 5.53 + 0.308*G4Exp(G4Log(G    381       fElasticXsc = 5.53 + 0.308*G4Exp(G4Log(G4Log(sMand/28.9))*1.1) 
382   + 9.19*G4Exp(-G4Log(sMand)*0.458);              382   + 9.19*G4Exp(-G4Log(sMand)*0.458);
383     }                                             383     }
384     else if( pLab >= 10.)                         384     else if( pLab >= 10.)
385     {                                             385     {
386       fElasticXsc =  6 + 20/( (logP-0.182)*(lo    386       fElasticXsc =  6 + 20/( (logP-0.182)*(logP-0.182) + 1.0 );
387     }                                             387     }
388     else  // pLab < 10 GeV/c                      388     else  // pLab < 10 GeV/c
389     {                                             389     {
390       if( neutron )      // nn to be pp           390       if( neutron )      // nn to be pp
391       {                                           391       {
392         G4double x = G4Log(pLab/0.73);            392         G4double x = G4Log(pLab/0.73);
393         if( pLab < 0.4 )                          393         if( pLab < 0.4 )
394         {                                         394         {
395           fTotalXsc = 23 + 50*std::sqrt(g4calc    395           fTotalXsc = 23 + 50*std::sqrt(g4calc->powN(-x, 7));
396           fElasticXsc = fTotalXsc;                396           fElasticXsc = fTotalXsc;
397         }                                         397         }
398         else if( pLab < 0.73 )                    398         else if( pLab < 0.73 )
399         {                                         399         {
400           fTotalXsc = 23 + 50*std::sqrt(g4calc    400           fTotalXsc = 23 + 50*std::sqrt(g4calc->powN(-x, 7));
401           fElasticXsc = fTotalXsc;                401           fElasticXsc = fTotalXsc; 
402         }                                         402         }
403         else if( pLab < 1.05  )                   403         else if( pLab < 1.05  )
404         {                                         404         {
405           fTotalXsc = 23 + 40*x*x;                405           fTotalXsc = 23 + 40*x*x;
406           fElasticXsc = 23 + 20*x*x;              406           fElasticXsc = 23 + 20*x*x;
407         }                                         407         }
408         else    // 1.05 - 10 GeV/c                408         else    // 1.05 - 10 GeV/c
409         {                                         409         {
410           fTotalXsc = 39.0+75*(pLab - 1.2)/(g4    410           fTotalXsc = 39.0+75*(pLab - 1.2)/(g4calc->powN(pLab,3) + 0.15);
411           fElasticXsc =  6 + 20/( (logP-0.182)    411           fElasticXsc =  6 + 20/( (logP-0.182)*(logP-0.182) + 1.0 );
412         }                                         412         }
413       }                                           413       }
414       if( proton )   // pn to be np               414       if( proton )   // pn to be np
415       {                                           415       {
416         if( pLab < 0.02 )                         416         if( pLab < 0.02 )
417         {                                         417         {
418           fTotalXsc = 4100+30*G4Exp(G4Log(G4Lo    418           fTotalXsc = 4100+30*G4Exp(G4Log(G4Log(1.3/pLab))*3.6); 
419     fElasticXsc = fTotalXsc;                      419     fElasticXsc = fTotalXsc;
420         }                                         420         }      
421         else if( pLab < 0.8 )                     421         else if( pLab < 0.8 )
422         {                                         422         {
423           fTotalXsc = 33+30*g4calc->powN(G4Log    423           fTotalXsc = 33+30*g4calc->powN(G4Log(pLab/1.3),4);
424     fElasticXsc = fTotalXsc;                      424     fElasticXsc = fTotalXsc;
425         }                                         425         }      
426         else if( pLab < 1.4 )                     426         else if( pLab < 1.4 )
427         {                                         427         {
428           fTotalXsc = 33+30*g4calc->powN(G4Log    428           fTotalXsc = 33+30*g4calc->powN(G4Log(pLab/0.95),2);
429           G4double x = G4Log(0.511/pLab);         429           G4double x = G4Log(0.511/pLab);
430           fElasticXsc =  6 + 52/( x*x + 1.6 );    430           fElasticXsc =  6 + 52/( x*x + 1.6 );
431         }                                         431         }
432         else    // 1.4 < pLab < 10.  )            432         else    // 1.4 < pLab < 10.  )
433         {                                         433         {
434           fTotalXsc = 33.3 + 20.8*(pLab*pLab -    434           fTotalXsc = 33.3 + 20.8*(pLab*pLab - 1.35)
435       /(std::sqrt(g4calc->powN(pLab,5)) + 0.95    435       /(std::sqrt(g4calc->powN(pLab,5)) + 0.95);
436           fElasticXsc =  6 + 20/( (logP-0.182)    436           fElasticXsc =  6 + 20/( (logP-0.182)*(logP-0.182) + 1.0 );
437         }                                         437         }
438       }                                           438       }
439     }                                             439     }
440   }                                               440   }
441   ////// proton //////////////////////////////    441   ////// proton //////////////////////////////////////////////
442   else if(theParticle == theProton)               442   else if(theParticle == theProton) 
443   {                                               443   {
444     if( pLab >= 373.) // pdg due to TOTEM data    444     if( pLab >= 373.) // pdg due to TOTEM data
445     {                                             445     {
446       fElasticXsc = 6.5 + 0.308*G4Exp(G4Log(G4    446       fElasticXsc = 6.5 + 0.308*G4Exp(G4Log(G4Log(sMand/400.))*1.65) 
447   + 9.19*G4Exp(-G4Log(sMand)*0.458);              447   + 9.19*G4Exp(-G4Log(sMand)*0.458);     
448     }                                             448     }
449     else if( pLab >= 100.)                        449     else if( pLab >= 100.)
450     {                                             450     {
451       fElasticXsc = 5.53 + 0.308*G4Exp(G4Log(G    451       fElasticXsc = 5.53 + 0.308*G4Exp(G4Log(G4Log(sMand/28.9))*1.1) 
452   + 9.19*G4Exp(-G4Log(sMand)*0.458);              452   + 9.19*G4Exp(-G4Log(sMand)*0.458);     
453     }                                             453     }
454     else if( pLab >= 10.)                         454     else if( pLab >= 10.)
455     {                                             455     {
456       fElasticXsc = 6. + 20./( (logP-0.182)*(l    456       fElasticXsc = 6. + 20./( (logP-0.182)*(logP-0.182) + 1.0 );
457     }                                             457     }
458     else                                          458     else
459     {                                             459     {
460       // pp                                       460       // pp
461       if( proton )                                461       if( proton )
462       {                                           462       {
463         if( pLab < 0.73 )                         463         if( pLab < 0.73 )
464         {                                         464         {
465           fTotalXsc = 23 + 50*std::sqrt(g4calc    465           fTotalXsc = 23 + 50*std::sqrt(g4calc->powN(G4Log(0.73/pLab),7));
466           fElasticXsc = fTotalXsc;                466           fElasticXsc = fTotalXsc;
467         }                                         467         }
468         else if( pLab < 1.05  )                   468         else if( pLab < 1.05  )
469         {                                         469         {
470     G4double x = G4Log(pLab/0.73);                470     G4double x = G4Log(pLab/0.73);
471           fTotalXsc = 23 + 40*x*x;                471           fTotalXsc = 23 + 40*x*x;
472           fElasticXsc = 23 + 20*x*x;              472           fElasticXsc = 23 + 20*x*x;
473         }                                         473         }
474         else    // 1.05 - 10 GeV/c                474         else    // 1.05 - 10 GeV/c
475         {                                         475         {
476           fTotalXsc = 39.0+75*(pLab - 1.2)/(g4    476           fTotalXsc = 39.0+75*(pLab - 1.2)/(g4calc->powN(pLab,3) + 0.15);
477           fElasticXsc = 6. + 20./( (logP-0.182    477           fElasticXsc = 6. + 20./( (logP-0.182)*(logP-0.182) + 1.0 );
478         }                                         478         }
479       }                                           479       }
480       else if( neutron )     // pn to be np       480       else if( neutron )     // pn to be np
481       {                                           481       {
482         if( pLab < 0.02 )                         482         if( pLab < 0.02 )
483         {                                         483         {
484           fTotalXsc = 4100+30*G4Exp(G4Log(G4Lo    484           fTotalXsc = 4100+30*G4Exp(G4Log(G4Log(1.3/pLab))*3.6); 
485     fElasticXsc = fTotalXsc;                      485     fElasticXsc = fTotalXsc;
486         }                                         486         }      
487         else if( pLab < 0.8 )                     487         else if( pLab < 0.8 )
488         {                                         488         {
489           fTotalXsc = 33+30*g4calc->powN(G4Log    489           fTotalXsc = 33+30*g4calc->powN(G4Log(pLab/1.3),4);
490     fElasticXsc = fTotalXsc;                      490     fElasticXsc = fTotalXsc;
491         }                                         491         }      
492         else if( pLab < 1.4 )                     492         else if( pLab < 1.4 )
493         {                                         493         {
494           G4double x1 = G4Log(pLab/0.95);         494           G4double x1 = G4Log(pLab/0.95);
495           G4double x2 = G4Log(0.511/pLab);        495           G4double x2 = G4Log(0.511/pLab);
496           fTotalXsc = 33+30*x1*x1;                496           fTotalXsc = 33+30*x1*x1;
497           fElasticXsc =  6 + 52/(x2*x2 + 1.6);    497           fElasticXsc =  6 + 52/(x2*x2 + 1.6);
498         }                                         498         }
499         else    // 1.4 < pLab < 10.  )            499         else    // 1.4 < pLab < 10.  )
500         {                                         500         {
501           fTotalXsc = 33.3 + 20.8*(pLab*pLab -    501           fTotalXsc = 33.3 + 20.8*(pLab*pLab - 1.35)
502       /(std::sqrt(g4calc->powN(pLab,5)) + 0.95    502       /(std::sqrt(g4calc->powN(pLab,5)) + 0.95);
503           fElasticXsc = 6. + 20./( (logP-0.182    503           fElasticXsc = 6. + 20./( (logP-0.182)*(logP-0.182) + 1.0 );
504         }                                         504         }
505       }                                           505       }
506     }                                             506     }    
507   }                                               507   }
508   // pi+ p; pi- n                                 508   // pi+ p; pi- n 
509   else if((pdg == 211 && proton) || (pdg == -2    509   else if((pdg == 211 && proton) || (pdg == -211 && neutron))  
510   {                                               510   {
511     if( pLab < 0.28 )                             511     if( pLab < 0.28 )
512     {                                             512     {
513       fTotalXsc = 10./((logP + 1.273)*(logP +     513       fTotalXsc = 10./((logP + 1.273)*(logP + 1.273) + 0.05);
514       fElasticXsc = fTotalXsc;                    514       fElasticXsc = fTotalXsc;
515     }                                             515     }
516     else if( pLab < 0.68 )                        516     else if( pLab < 0.68 )
517     {                                             517     {
518       fTotalXsc = 14./((logP + 1.273)*(logP +     518       fTotalXsc = 14./((logP + 1.273)*(logP + 1.273) + 0.07);
519       fElasticXsc = fTotalXsc;                    519       fElasticXsc = fTotalXsc;
520     }                                             520     }
521     else if( pLab < 0.85 )                        521     else if( pLab < 0.85 )
522     {                                             522     {
523       G4double x = G4Log(pLab/0.77);              523       G4double x = G4Log(pLab/0.77);
524       fTotalXsc = 88.*x*x + 14.9;                 524       fTotalXsc = 88.*x*x + 14.9;
525       fElasticXsc = fTotalXsc*G4Exp(-3.*(pLab     525       fElasticXsc = fTotalXsc*G4Exp(-3.*(pLab - 0.68));  
526     }                                             526     }
527     else if( pLab < 1.15 )                        527     else if( pLab < 1.15 )
528     {                                             528     {
529       G4double x = G4Log(pLab/0.77);              529       G4double x = G4Log(pLab/0.77);
530       fTotalXsc = 88.*x*x + 14.9;                 530       fTotalXsc = 88.*x*x + 14.9;
531       fElasticXsc = 6.0 + 1.4/(( pLab - 1.4)*(    531       fElasticXsc = 6.0 + 1.4/(( pLab - 1.4)*( pLab - 1.4) + 0.1);
532     }                                             532     }
533     else if( pLab < 1.4) // ns original           533     else if( pLab < 1.4) // ns original
534     {                                             534     {
535       G4double Ex1 = 3.2*G4Exp(-(pLab-2.55)*(p    535       G4double Ex1 = 3.2*G4Exp(-(pLab-2.55)*(pLab-2.55)/0.55/0.55);
536       G4double Ex2 = 12*G4Exp(-(pLab-1.47)*(pL    536       G4double Ex2 = 12*G4Exp(-(pLab-1.47)*(pLab-1.47)/0.225/0.225);
537       fTotalXsc       = Ex1 + Ex2 + 27.5;         537       fTotalXsc       = Ex1 + Ex2 + 27.5;
538       fElasticXsc = 6.0 + 1.4/(( pLab - 1.4)*(    538       fElasticXsc = 6.0 + 1.4/(( pLab - 1.4)*( pLab - 1.4) + 0.1);
539     }                                             539     }
540     else if( pLab < 2.0 ) // ns original          540     else if( pLab < 2.0 ) // ns original
541     {                                             541     {
542       G4double Ex1 = 3.2*G4Exp(-(pLab-2.55)*(p    542       G4double Ex1 = 3.2*G4Exp(-(pLab-2.55)*(pLab-2.55)/0.55/0.55);
543       G4double Ex2 = 12*G4Exp(-(pLab-1.47)*(pL    543       G4double Ex2 = 12*G4Exp(-(pLab-1.47)*(pLab-1.47)/0.225/0.225);
544       fTotalXsc     = Ex1 + Ex2 + 27.5;           544       fTotalXsc     = Ex1 + Ex2 + 27.5;
545       fElasticXsc = 3.0 + 1.36/( (logP - 0.336    545       fElasticXsc = 3.0 + 1.36/( (logP - 0.336)*(logP - 0.336) + 0.08);    
546     }                                             546     }
547     else if( pLab < 3.5 ) // ns original          547     else if( pLab < 3.5 ) // ns original
548     {                                             548     {
549       G4double Ex1 = 3.2*G4Exp(-(pLab-2.55)*(p    549       G4double Ex1 = 3.2*G4Exp(-(pLab-2.55)*(pLab-2.55)/0.55/0.55);
550       G4double Ex2 = 12*G4Exp(-(pLab-1.47)*(pL    550       G4double Ex2 = 12*G4Exp(-(pLab-1.47)*(pLab-1.47)/0.225/0.225);
551       fTotalXsc       = Ex1 + Ex2 + 27.5;         551       fTotalXsc       = Ex1 + Ex2 + 27.5;
552       fElasticXsc = 3.0 + 6.20/( (logP - 0.336    552       fElasticXsc = 3.0 + 6.20/( (logP - 0.336)*(logP - 0.336) + 0.8);    
553     }                                             553     }
554     else if( pLab < 10. ) // my                   554     else if( pLab < 10. ) // my
555     {                                             555     {
556       fTotalXsc = 10.6 + 2.*G4Log(pE) + 25*G4E    556       fTotalXsc = 10.6 + 2.*G4Log(pE) + 25*G4Exp(-G4Log(pE)*0.43 ); 
557       fElasticXsc = 3.0 + 6.20/( (logP - 0.336    557       fElasticXsc = 3.0 + 6.20/( (logP - 0.336)*(logP - 0.336) + 0.8);    
558     }                                             558     }
559     else //  pLab > 10 // my                      559     else //  pLab > 10 // my
560     {                                             560     {
561       fElasticXsc = 3.0 + 6.20/( (logP - 0.336    561       fElasticXsc = 3.0 + 6.20/( (logP - 0.336)*(logP - 0.336) + 0.8);    
562     }                                             562     }
563   }                                               563   }
564   // pi+ n; pi- p                                 564   // pi+ n; pi- p
565   else if((pdg == 211 && neutron) || (pdg == -    565   else if((pdg == 211 && neutron) || (pdg == -211 && proton))  
566   {                                               566   {
567     if( pLab < 0.28 )                             567     if( pLab < 0.28 ) 
568     {                                             568     {
569       fTotalXsc = 0.288/((pLab - 0.28)*(pLab -    569       fTotalXsc = 0.288/((pLab - 0.28)*(pLab - 0.28) + 0.004);
570       fElasticXsc = 1.8/((logP + 1.273)*(logP     570       fElasticXsc = 1.8/((logP + 1.273)*(logP + 1.273) + 0.07);
571     }                                             571     }
572     else if( pLab < 0.395676 ) // first peak      572     else if( pLab < 0.395676 ) // first peak
573     {                                             573     {
574       fTotalXsc = 0.648/((pLab - 0.28)*(pLab -    574       fTotalXsc = 0.648/((pLab - 0.28)*(pLab - 0.28) + 0.009);
575       fElasticXsc = 0.257/((pLab - 0.28)*(pLab    575       fElasticXsc = 0.257/((pLab - 0.28)*(pLab - 0.28) + 0.01);
576     }                                             576     }
577     else if( pLab < 0.5 )                         577     else if( pLab < 0.5 )
578     {                                             578     {
579       G4double y = G4Log(pLab/0.48);              579       G4double y = G4Log(pLab/0.48);
580       fTotalXsc = 26 + 110*y*y;                   580       fTotalXsc = 26 + 110*y*y;
581       fElasticXsc = 0.37*fTotalXsc;               581       fElasticXsc = 0.37*fTotalXsc;
582     }                                             582     }
583     else if( pLab < 0.65 )                        583     else if( pLab < 0.65 )
584     {                                             584     {
585       G4double x = G4Log(pLab/0.48);              585       G4double x = G4Log(pLab/0.48);
586       fTotalXsc = 26. + 110.*x*x;                 586       fTotalXsc = 26. + 110.*x*x;
587       fElasticXsc = 0.95/((pLab - 0.72)*(pLab     587       fElasticXsc = 0.95/((pLab - 0.72)*(pLab - 0.72) + 0.049);
588     }                                             588     }
589     else if( pLab < 0.72 )                        589     else if( pLab < 0.72 )
590     {                                             590     {
591       fTotalXsc = 36.1 + 10*G4Exp(-(pLab-0.72)    591       fTotalXsc = 36.1 + 10*G4Exp(-(pLab-0.72)*(pLab-0.72)/0.06/0.06)+
592   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.    592   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.075);
593       fElasticXsc = 0.95/((pLab - 0.72)*(pLab     593       fElasticXsc = 0.95/((pLab - 0.72)*(pLab - 0.72) + 0.049);
594     }                                             594     }
595     else if( pLab < 0.88 )                        595     else if( pLab < 0.88 )
596     {                                             596     {
597       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72    597       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72)*(pLab-0.72)/0.06/0.06)+
598   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.    598   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.075);
599       fElasticXsc = 0.95/((pLab - 0.72)*(pLab     599       fElasticXsc = 0.95/((pLab - 0.72)*(pLab - 0.72) + 0.049);
600     }                                             600     }
601     else if( pLab < 1.03 )                        601     else if( pLab < 1.03 )
602     {                                             602     {
603       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72    603       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72)*(pLab-0.72)/0.06/0.06)+
604   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.    604   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.075);
605       fElasticXsc = 2.0 + 0.4/((pLab - 1.03)*(    605       fElasticXsc = 2.0 + 0.4/((pLab - 1.03)*(pLab - 1.03) + 0.016);
606     }                                             606     }
607     else if( pLab < 1.15 )                        607     else if( pLab < 1.15 )
608     {                                             608     {
609       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72    609       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72)*(pLab-0.72)/0.06/0.06)+
610   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.    610   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.075);
611       fElasticXsc = 2.0 + 0.4/((pLab - 1.03)*(    611       fElasticXsc = 2.0 + 0.4/((pLab - 1.03)*(pLab - 1.03) + 0.016);
612     }                                             612     }
613     else if( pLab < 1.3 )                         613     else if( pLab < 1.3 )
614     {                                             614     {
615       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72    615       fTotalXsc = 36.1 + 10.*G4Exp(-(pLab-0.72)*(pLab-0.72)/0.06/0.06)+
616   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.    616   24*G4Exp(-(pLab-1.015)*(pLab-1.015)/0.075/0.075);
617       fElasticXsc = 3. + 13./pLab;                617       fElasticXsc = 3. + 13./pLab;
618     }                                             618     }
619     else if( pLab < 10.) // < 3.0) // ns origi    619     else if( pLab < 10.) // < 3.0) // ns original
620     {                                             620     {
621       fTotalXsc = 36.1 + 0.079-4.313*logP+        621       fTotalXsc = 36.1 + 0.079-4.313*logP+
622   3*G4Exp(-(pLab-2.1)*(pLab-2.1)/0.4/0.4)+        622   3*G4Exp(-(pLab-2.1)*(pLab-2.1)/0.4/0.4)+
623   1.5*G4Exp(-(pLab-1.4)*(pLab-1.4)/0.12/0.12);    623   1.5*G4Exp(-(pLab-1.4)*(pLab-1.4)/0.12/0.12);
624       fElasticXsc = 3. + 13./pLab;                624       fElasticXsc = 3. + 13./pLab; 
625     }                                             625     }
626     else   // mb                                  626     else   // mb 
627     {                                             627     {
628       fElasticXsc = 3. + 13./pLab;                628       fElasticXsc = 3. + 13./pLab;
629     }                                             629     }
630   }                                               630   }
631   else if( (theParticle == theKMinus) && proto    631   else if( (theParticle == theKMinus) && proton )   // K-p
632   {                                               632   {
633     if( pLab < pMin)                              633     if( pLab < pMin)
634     {                                             634     {
635       G4double psp = pLab*std::sqrt(pLab);        635       G4double psp = pLab*std::sqrt(pLab);
636       fElasticXsc  = 5.2/psp;                     636       fElasticXsc  = 5.2/psp;
637       fTotalXsc    = 14./psp;                     637       fTotalXsc    = 14./psp;
638     }                                             638     }
639     else if( pLab > pMax )                        639     else if( pLab > pMax )
640     {                                             640     {
641       G4double ld  = logP - minLogP;              641       G4double ld  = logP - minLogP;
642       G4double ld2 = ld*ld;                       642       G4double ld2 = ld*ld;
643       fElasticXsc  = cofLogE*ld2 + 2.23;          643       fElasticXsc  = cofLogE*ld2 + 2.23;
644       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;      644       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;
645     }                                             645     }
646     else                                          646     else
647     {                                             647     {
648       G4double ld  = logP - minLogP;              648       G4double ld  = logP - minLogP;
649       G4double ld2 = ld*ld;                       649       G4double ld2 = ld*ld;
650       G4double sp  = std::sqrt(pLab);             650       G4double sp  = std::sqrt(pLab);
651       G4double psp = pLab*sp;                     651       G4double psp = pLab*sp;
652       G4double p2  = pLab*pLab;                   652       G4double p2  = pLab*pLab;
653       G4double p4  = p2*p2;                       653       G4double p4  = p2*p2;
654                                                   654 
655       G4double lh  = pLab - 1.01;                 655       G4double lh  = pLab - 1.01;
656       G4double hd  = lh*lh + .011;                656       G4double hd  = lh*lh + .011;
657                                                   657 
658       G4double lm  = pLab - .39;                  658       G4double lm  = pLab - .39;
659       G4double md  = lm*lm + .000356;             659       G4double md  = lm*lm + .000356;
660       G4double lh1  = pLab - 0.78;                660       G4double lh1  = pLab - 0.78;
661       G4double hd1  = lh1*lh1 + .00166;           661       G4double hd1  = lh1*lh1 + .00166;
662       G4double lh2  = pLab - 1.63;                662       G4double lh2  = pLab - 1.63;
663       G4double hd2  = lh2*lh2 + .007;             663       G4double hd2  = lh2*lh2 + .007;
664                                                   664 
665       // small peaks were added but commented     665       // small peaks were added but commented out now
666       fElasticXsc  = 5.2/psp + (1.1*cofLogE*ld    666       fElasticXsc  = 5.2/psp + (1.1*cofLogE*ld2 + 2.23)/(1. - .7/sp + .075/p4) 
667   + .004/md + 0.005/hd1+ 0.01/hd2 +.15/hd;        667   + .004/md + 0.005/hd1+ 0.01/hd2 +.15/hd; 
668                                                   668 
669       fTotalXsc   = 14./psp + (1.1*cofLogT*ld2    669       fTotalXsc   = 14./psp + (1.1*cofLogT*ld2 + 19.5)/(1. - .21/sp + .52/p4) 
670         + .006/md  + 0.01/hd1+ 0.02/hd2 + .20/    670         + .006/md  + 0.01/hd1+ 0.02/hd2 + .20/hd ;
671     }                                             671     }
672   }                                               672   }
673   else if( (theParticle == theKMinus) && neutr    673   else if( (theParticle == theKMinus) && neutron )  // K-n
674   {                                               674   {
675     if( pLab > pMax )                             675     if( pLab > pMax )
676     {                                             676     {
677       G4double ld  = logP - minLogP;              677       G4double ld  = logP - minLogP;
678       G4double ld2 = ld*ld;                       678       G4double ld2 = ld*ld;
679       fElasticXsc  = cofLogE*ld2 + 2.23;          679       fElasticXsc  = cofLogE*ld2 + 2.23;
680       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;      680       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;
681     }                                             681     }
682     else                                          682     else
683     {                                             683     { 
684       G4double lh  = pLab - 0.98;                 684       G4double lh  = pLab - 0.98;
685       G4double hd  = lh*lh + .021;                685       G4double hd  = lh*lh + .021; 
686       G4double sqrLogPlab = logP*logP;            686       G4double sqrLogPlab = logP*logP;
687                                                   687 
688       fElasticXsc = 5.0 +  8.1*G4Exp(-logP*1.8    688       fElasticXsc = 5.0 +  8.1*G4Exp(-logP*1.8) + 0.16*sqrLogPlab 
689   - 1.3*logP + .15/hd;                            689   - 1.3*logP + .15/hd;
690       fTotalXsc = 25.2 +  0.38*sqrLogPlab - 2.    690       fTotalXsc = 25.2 +  0.38*sqrLogPlab - 2.9*logP + 0.30/hd;
691     }                                             691     }
692   }                                               692   }
693   else if( (theParticle == theKPlus) && proton    693   else if( (theParticle == theKPlus) && proton  )  // K+p
694   {                                               694   {
695     // VI: modified low-energy part               695     // VI: modified low-energy part
696     if( pLab < 0.631 )                            696     if( pLab < 0.631 )
697     {                                             697     {
698       fElasticXsc = fTotalXsc = 12.03;            698       fElasticXsc = fTotalXsc = 12.03;
699     }                                             699     }
700     else if( pLab > pMax )                        700     else if( pLab > pMax )
701     {                                             701     {
702       G4double ld  = logP - minLogP;              702       G4double ld  = logP - minLogP;
703       G4double ld2 = ld*ld;                       703       G4double ld2 = ld*ld;
704       fElasticXsc  = cofLogE*ld2 + 2.23;          704       fElasticXsc  = cofLogE*ld2 + 2.23;
705       fTotalXsc    = cofLogT*ld2 + 19.2;          705       fTotalXsc    = cofLogT*ld2 + 19.2;
706     }                                             706     }
707     else                                          707     else
708     {                                             708     {
709       G4double ld  = logP - minLogP;              709       G4double ld  = logP - minLogP;
710       G4double ld2 = ld*ld;                       710       G4double ld2 = ld*ld;
711       G4double lr  = pLab - .38;                  711       G4double lr  = pLab - .38;
712       G4double LE  = .7/(lr*lr + .076);           712       G4double LE  = .7/(lr*lr + .076);
713       G4double sp  = std::sqrt(pLab);             713       G4double sp  = std::sqrt(pLab);
714       G4double p2  = pLab*pLab;                   714       G4double p2  = pLab*pLab;
715       G4double p4  = p2*p2;                       715       G4double p4  = p2*p2;
716       // VI: tuned elastic                        716       // VI: tuned elastic
717       fElasticXsc  = LE + (cofLogE*ld2 + 2.23)    717       fElasticXsc  = LE + (cofLogE*ld2 + 2.23)/(1. - .7/sp + .1/p4) 
718   + 2./((pLab - 0.8)*(pLab - 0.8) + 0.652);       718   + 2./((pLab - 0.8)*(pLab - 0.8) + 0.652);
719       fTotalXsc    = LE + (cofLogT*ld2 + 19.5)    719       fTotalXsc    = LE + (cofLogT*ld2 + 19.5)/(1. + .46/sp + 1.6/p4) 
720   + 2.6/((pLab - 1.)*(pLab - 1.) + 0.392);        720   + 2.6/((pLab - 1.)*(pLab - 1.) + 0.392);
721     }                                             721     }
722   }                                               722   }
723   else if(  (theParticle == theKPlus) && neutr    723   else if(  (theParticle == theKPlus) && neutron) // K+n  
724   {                                               724   {
725     if( pLab < pMin )                             725     if( pLab < pMin )
726     {                                             726     {
727       G4double lm = pLab - 0.94;                  727       G4double lm = pLab - 0.94;
728       G4double md = lm*lm + .392;                 728       G4double md = lm*lm + .392;   
729       fElasticXsc = 2./md;                        729       fElasticXsc = 2./md;
730       fTotalXsc   = 4.6/md;                       730       fTotalXsc   = 4.6/md;
731     }                                             731     }
732     else if( pLab > pMax )                        732     else if( pLab > pMax )
733     {                                             733     {
734       G4double ld  = logP - minLogP;              734       G4double ld  = logP - minLogP;
735       G4double ld2 = ld*ld;                       735       G4double ld2 = ld*ld;
736       fElasticXsc  = cofLogE*ld2 + 2.23;          736       fElasticXsc  = cofLogE*ld2 + 2.23;
737       fTotalXsc    = cofLogT*ld2 + 19.2;          737       fTotalXsc    = cofLogT*ld2 + 19.2;
738     }                                             738     }
739     else                                          739     else
740     {                                             740     {
741       G4double ld  = logP - minLogP;              741       G4double ld  = logP - minLogP;
742       G4double ld2 = ld*ld;                       742       G4double ld2 = ld*ld;
743       G4double sp  = std::sqrt(pLab);             743       G4double sp  = std::sqrt(pLab);
744       G4double p2  = pLab*pLab;                   744       G4double p2  = pLab*pLab;
745       G4double p4  = p2*p2;                       745       G4double p4  = p2*p2;
746       G4double lm  = pLab - 0.94;                 746       G4double lm  = pLab - 0.94;
747       G4double md  = lm*lm + .392;                747       G4double md  = lm*lm + .392; 
748       fElasticXsc  = (cofLogE*ld2 + 2.23)/(1.     748       fElasticXsc  = (cofLogE*ld2 + 2.23)/(1. - .7/sp + .1/p4) + 2./md;
749       fTotalXsc    = (cofLogT*ld2 + 19.5)/(1.     749       fTotalXsc    = (cofLogT*ld2 + 19.5)/(1. + .46/sp + 1.6/p4) + 4.6/md;
750     }                                             750     }
751   }                                               751   }
752   fTotalXsc   *= CLHEP::millibarn;                752   fTotalXsc   *= CLHEP::millibarn; 
753   fElasticXsc *= CLHEP::millibarn;                753   fElasticXsc *= CLHEP::millibarn;
754   fElasticXsc  = std::min(fElasticXsc, fTotalX    754   fElasticXsc  = std::min(fElasticXsc, fTotalXsc);
755                                                   755 
756   if( proton && theParticle->GetPDGCharge() >     756   if( proton && theParticle->GetPDGCharge() > 0. && ekin < ekinmaxQB )
757   {                                               757   {
758     G4double cB = G4NuclearRadii::CoulombFacto    758     G4double cB = G4NuclearRadii::CoulombFactor(theParticle, nucleon, ekin);
759     fTotalXsc   *= cB;                            759     fTotalXsc   *= cB;
760     fElasticXsc *= cB;                            760     fElasticXsc *= cB; 
761   }                                               761   }
762   fInelasticXsc = std::max(fTotalXsc - fElasti    762   fInelasticXsc = std::max(fTotalXsc - fElasticXsc,0.0);
763   /*                                              763   /*
764   G4cout<< "HNXsc: Ekin(GeV)= " << ekin/GeV <<    764   G4cout<< "HNXsc: Ekin(GeV)= " << ekin/GeV << "; tot(mb)= " << fTotalXsc/millibarn
765         <<"; el(mb)= " <<fElasticXsc/millibarn    765         <<"; el(mb)= " <<fElasticXsc/millibarn
766         <<"; inel(mb)= " <<fInelasticXsc/milli    766         <<"; inel(mb)= " <<fInelasticXsc/millibarn<<"  "
767         << theParticle->GetParticleName() << "    767         << theParticle->GetParticleName() << " + " 
768         << nucleon->GetParticleName() << G4end    768         << nucleon->GetParticleName() << G4endl;
769   */                                              769   */
770   return fTotalXsc;                               770   return fTotalXsc;
771 }                                                 771 }
772                                                   772 
773 //////////////////////////////////////////////    773 //////////////////////////////////////////////////////////////////////////////
774 //                                                774 //
775 // Returns kaon-nucleon cross-section based on    775 // Returns kaon-nucleon cross-section based on smoothed NS 
776 // tuned for the Glauber-Gribov hadron model f    776 // tuned for the Glauber-Gribov hadron model for Z>1
777                                                   777 
778 G4double G4HadronNucleonXsc::KaonNucleonXscGG(    778 G4double G4HadronNucleonXsc::KaonNucleonXscGG(
779                              const G4ParticleD    779                              const G4ParticleDefinition* theParticle, 
780            const G4ParticleDefinition* nucleon    780            const G4ParticleDefinition* nucleon, G4double ekin)
781 {                                                 781 {
782   fTotalXsc = fElasticXsc = fInelasticXsc = 0.    782   fTotalXsc = fElasticXsc = fInelasticXsc = 0.0;
783   if(theParticle == theKMinus || theParticle =    783   if(theParticle == theKMinus || theParticle == theKPlus) {
784     KaonNucleonXscVG(theParticle, nucleon, eki    784     KaonNucleonXscVG(theParticle, nucleon, ekin);
785                                                   785 
786   } else if(theParticle == theK0S || thePartic    786   } else if(theParticle == theK0S || theParticle == theK0L) {
787     G4double stot  = KaonNucleonXscVG(theKMinu    787     G4double stot  = KaonNucleonXscVG(theKMinus, nucleon, ekin);
788     G4double sel   = fElasticXsc;                 788     G4double sel   = fElasticXsc;
789     G4double sinel = fInelasticXsc;               789     G4double sinel = fInelasticXsc;
790     stot  += KaonNucleonXscVG(theKPlus, nucleo    790     stot  += KaonNucleonXscVG(theKPlus, nucleon, ekin);
791     sel   += fElasticXsc;                         791     sel   += fElasticXsc;
792     sinel += fInelasticXsc;                       792     sinel += fInelasticXsc;
793     fTotalXsc = stot*0.5;                         793     fTotalXsc = stot*0.5; 
794     fElasticXsc = sel*0.5;                        794     fElasticXsc = sel*0.5; 
795     fInelasticXsc = sinel*0.5;                    795     fInelasticXsc = sinel*0.5;
796   }                                               796   }
797   return fTotalXsc;                               797   return fTotalXsc;
798 }                                                 798 }
799                                                   799 
800 //////////////////////////////////////////////    800 //////////////////////////////////////////////////////////////////////////////
801 //                                                801 //
802 // Returns kaon-nucleon cross-section using NS    802 // Returns kaon-nucleon cross-section using NS
803                                                   803 
804 G4double G4HadronNucleonXsc::KaonNucleonXscNS(    804 G4double G4HadronNucleonXsc::KaonNucleonXscNS(
805                              const G4ParticleD    805                              const G4ParticleDefinition* theParticle, 
806            const G4ParticleDefinition* nucleon    806            const G4ParticleDefinition* nucleon, G4double ekin)
807 {                                                 807 {
808   fTotalXsc = fElasticXsc = fInelasticXsc = 0.    808   fTotalXsc = fElasticXsc = fInelasticXsc = 0.0;
809   if(theParticle == theKMinus || theParticle =    809   if(theParticle == theKMinus || theParticle == theKPlus) {
810     HadronNucleonXscNS(theParticle, nucleon, e    810     HadronNucleonXscNS(theParticle, nucleon, ekin);
811                                                   811 
812   } else if(theParticle == theK0S || thePartic    812   } else if(theParticle == theK0S || theParticle == theK0L) {
813     G4double fact = 0.5;                          813     G4double fact = 0.5;
814     G4double stot = 0.0;                          814     G4double stot = 0.0;
815     G4double sel  = 0.0;                          815     G4double sel  = 0.0;
816     G4double sinel= 0.0;                          816     G4double sinel= 0.0;
817     if(ekin > ekinmaxQB) {                        817     if(ekin > ekinmaxQB) {
818       stot  = HadronNucleonXscNS(theKMinus, nu    818       stot  = HadronNucleonXscNS(theKMinus, nucleon, ekin);
819       sel   = fElasticXsc;                        819       sel   = fElasticXsc;
820       sinel = fInelasticXsc;                      820       sinel = fInelasticXsc;
821       stot  += HadronNucleonXscNS(theKPlus, nu    821       stot  += HadronNucleonXscNS(theKPlus, nucleon, ekin);
822       sel   += fElasticXsc;                       822       sel   += fElasticXsc;
823       sinel += fInelasticXsc;                     823       sinel += fInelasticXsc;
824     } else {                                      824     } else {
825       fact *= std::sqrt(ekinmaxQB/std::max(eki    825       fact *= std::sqrt(ekinmaxQB/std::max(ekin, ekinmin));
826       stot  = HadronNucleonXscNS(theKMinus, nu    826       stot  = HadronNucleonXscNS(theKMinus, nucleon, ekinmaxQB);
827       sel   = fElasticXsc;                        827       sel   = fElasticXsc;
828       sinel = fInelasticXsc;                      828       sinel = fInelasticXsc;
829       stot  += HadronNucleonXscNS(theKPlus, nu    829       stot  += HadronNucleonXscNS(theKPlus, nucleon, ekinmaxQB);
830       sel   += fElasticXsc;                       830       sel   += fElasticXsc;
831       sinel += fInelasticXsc;                     831       sinel += fInelasticXsc;
832     }                                             832     }
833     fTotalXsc = stot*fact;                        833     fTotalXsc = stot*fact; 
834     fElasticXsc = sel*fact;                       834     fElasticXsc = sel*fact; 
835     fInelasticXsc = sinel*fact;                   835     fInelasticXsc = sinel*fact;
836   }                                               836   }
837   return fTotalXsc;                               837   return fTotalXsc;
838 }                                                 838 }
839                                                   839 
840 //////////////////////////////////////////////    840 //////////////////////////////////////////////////////////////////////////////
841 //                                                841 //
842 // Returns kaon-nucleon cross-section with smo    842 // Returns kaon-nucleon cross-section with smoothed NS parameterisation
843                                                   843 
844 G4double G4HadronNucleonXsc::KaonNucleonXscVG(    844 G4double G4HadronNucleonXsc::KaonNucleonXscVG(
845                  const G4ParticleDefinition* t    845                  const G4ParticleDefinition* theParticle, 
846      const G4ParticleDefinition* nucleon, G4do    846      const G4ParticleDefinition* nucleon, G4double ekin)
847 {                                                 847 {
848   G4double pM   = theParticle->GetPDGMass();      848   G4double pM   = theParticle->GetPDGMass();
849   G4double pLab = std::sqrt(ekin*(ekin + 2*pM)    849   G4double pLab = std::sqrt(ekin*(ekin + 2*pM));
850                                                   850 
851   pLab *= invGeV;                                 851   pLab *= invGeV;
852   G4double logP = G4Log(pLab);                    852   G4double logP = G4Log(pLab);
853                                                   853 
854   fTotalXsc = 0.0;                                854   fTotalXsc = 0.0;
855                                                   855 
856   G4bool proton = (nucleon == theProton);         856   G4bool proton = (nucleon == theProton);
857   G4bool neutron = (nucleon == theNeutron);       857   G4bool neutron = (nucleon == theNeutron);
858                                                   858 
859   if( (theParticle == theKMinus) && proton )      859   if( (theParticle == theKMinus) && proton )   // K-p
860   {                                               860   {
861     if( pLab < pMin)                              861     if( pLab < pMin)
862     {                                             862     {
863       G4double psp = pLab*std::sqrt(pLab);        863       G4double psp = pLab*std::sqrt(pLab);
864       fElasticXsc  = 5.2/psp;                     864       fElasticXsc  = 5.2/psp;
865       fTotalXsc    = 14./psp;                     865       fTotalXsc    = 14./psp;
866     }                                             866     }
867     else if( pLab > pMax )                        867     else if( pLab > pMax )
868     {                                             868     {
869       G4double ld  = logP - minLogP;              869       G4double ld  = logP - minLogP;
870       G4double ld2 = ld*ld;                       870       G4double ld2 = ld*ld;
871       fElasticXsc  = cofLogE*ld2 + 2.23;          871       fElasticXsc  = cofLogE*ld2 + 2.23;
872       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;      872       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;
873     }                                             873     }
874     else                                          874     else
875     {                                             875     {
876       G4double ld  = logP - minLogP;              876       G4double ld  = logP - minLogP;
877       G4double ld2 = ld*ld;                       877       G4double ld2 = ld*ld;
878       G4double sp  = std::sqrt(pLab);             878       G4double sp  = std::sqrt(pLab);
879       G4double psp = pLab*sp;                     879       G4double psp = pLab*sp;
880       G4double p2  = pLab*pLab;                   880       G4double p2  = pLab*pLab;
881       G4double p4  = p2*p2;                       881       G4double p4  = p2*p2;
882                                                   882 
883       G4double lh  = pLab - 1.01;                 883       G4double lh  = pLab - 1.01;
884       G4double hd  = lh*lh + .011;                884       G4double hd  = lh*lh + .011;
885       fElasticXsc  = 5.2/psp + (cofLogE*ld2 +     885       fElasticXsc  = 5.2/psp + (cofLogE*ld2 + 2.23)/(1. - .7/sp + .075/p4) + .15/hd;
886       fTotalXsc    = 14./psp + (1.1*cofLogT*ld    886       fTotalXsc    = 14./psp + (1.1*cofLogT*ld2 + 19.5)/(1. - .21/sp + .52/p4) + .60/hd;
887     }                                             887     }
888   }                                               888   }
889   else if( (theParticle == theKMinus) && neutr    889   else if( (theParticle == theKMinus) && neutron )  // K-n
890   {                                               890   {
891     if( pLab > pMax )                             891     if( pLab > pMax )
892     {                                             892     {
893       G4double ld  = logP - minLogP;              893       G4double ld  = logP - minLogP;
894       G4double ld2 = ld*ld;                       894       G4double ld2 = ld*ld;
895       fElasticXsc  = cofLogE*ld2 + 2.23;          895       fElasticXsc  = cofLogE*ld2 + 2.23;
896       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;      896       fTotalXsc    = 1.1*cofLogT*ld2 + 19.7;
897     }                                             897     }
898     else                                          898     else
899     {                                             899     { 
900       G4double lh  = pLab - 0.98;                 900       G4double lh  = pLab - 0.98;
901       G4double hd  = lh*lh + .045;    // vg ve    901       G4double hd  = lh*lh + .045;    // vg version
902       G4double sqrLogPlab = logP*logP;            902       G4double sqrLogPlab = logP*logP;
903                                                   903 
904       fElasticXsc = 5.0 +  8.1*G4Exp(-logP*1.8    904       fElasticXsc = 5.0 +  8.1*G4Exp(-logP*1.8) + 0.16*sqrLogPlab 
905   - 1.3*logP + .15/hd;                            905   - 1.3*logP + .15/hd;
906       fTotalXsc = 25.2 +  0.38*sqrLogPlab - 2.    906       fTotalXsc = 25.2 +  0.38*sqrLogPlab - 2.9*logP + 0.60/hd;  // vg version
907     }                                             907     }
908   }                                               908   }
909   else if( (theParticle == theKPlus) && proton    909   else if( (theParticle == theKPlus) && proton  )  // K+p
910   {                                               910   {
911     // VI: modified low-energy part               911     // VI: modified low-energy part
912     if( pLab < 0.631 )                            912     if( pLab < 0.631 )
913     {                                             913     {
914       fElasticXsc = fTotalXsc = 12.03;            914       fElasticXsc = fTotalXsc = 12.03;
915     }                                             915     }
916     else if( pLab > pMax )                        916     else if( pLab > pMax )
917     {                                             917     {
918       G4double ld  = logP - minLogP;              918       G4double ld  = logP - minLogP;
919       G4double ld2 = ld*ld;                       919       G4double ld2 = ld*ld;
920       fElasticXsc  = cofLogE*ld2 + 2.23;          920       fElasticXsc  = cofLogE*ld2 + 2.23;
921       fTotalXsc    = cofLogT*ld2 + 19.2;          921       fTotalXsc    = cofLogT*ld2 + 19.2;
922     }                                             922     }
923     else                                          923     else
924     {                                             924     {
925       G4double ld  = logP - minLogP;              925       G4double ld  = logP - minLogP;
926       G4double ld2 = ld*ld;                       926       G4double ld2 = ld*ld;
927       G4double lr  = pLab - .38;                  927       G4double lr  = pLab - .38;
928       G4double LE  = .7/(lr*lr + .076);           928       G4double LE  = .7/(lr*lr + .076);
929       G4double sp  = std::sqrt(pLab);             929       G4double sp  = std::sqrt(pLab);
930       G4double p2  = pLab*pLab;                   930       G4double p2  = pLab*pLab;
931       G4double p4  = p2*p2;                       931       G4double p4  = p2*p2;
932       // VI: tuned elastic                        932       // VI: tuned elastic
933       fElasticXsc  = LE + (cofLogE*ld2 + 2.23)    933       fElasticXsc  = LE + (cofLogE*ld2 + 2.23)/(1. - .7/sp + .1/p4) 
934   + 2./((pLab - 0.8)*(pLab - 0.8) + 0.652);       934   + 2./((pLab - 0.8)*(pLab - 0.8) + 0.652);
935       fTotalXsc    = LE + (cofLogT*ld2 + 19.5)    935       fTotalXsc    = LE + (cofLogT*ld2 + 19.5)/(1. + .46/sp + 1.6/p4) 
936   + 2.6/((pLab - 1.)*(pLab - 1.) + 0.392);        936   + 2.6/((pLab - 1.)*(pLab - 1.) + 0.392);
937     }                                             937     }
938   }                                               938   }
939   else if(  (theParticle == theKPlus) && neutr    939   else if(  (theParticle == theKPlus) && neutron) // K+n  
940   {                                               940   {
941     if( pLab < pMin )                             941     if( pLab < pMin )
942     {                                             942     {
943       G4double lm = pLab - 0.94;                  943       G4double lm = pLab - 0.94;
944       G4double md = lm*lm + .392;                 944       G4double md = lm*lm + .392;   
945       fElasticXsc = 2./md;                        945       fElasticXsc = 2./md;
946       fTotalXsc   = 4.6/md;                       946       fTotalXsc   = 4.6/md;
947     }                                             947     }
948     else if( pLab > pMax )                        948     else if( pLab > pMax )
949     {                                             949     {
950       G4double ld  = logP - minLogP;              950       G4double ld  = logP - minLogP;
951       G4double ld2 = ld*ld;                       951       G4double ld2 = ld*ld;
952       fElasticXsc  = cofLogE*ld2 + 2.23;          952       fElasticXsc  = cofLogE*ld2 + 2.23;
953       fTotalXsc    = cofLogT*ld2 + 19.2;          953       fTotalXsc    = cofLogT*ld2 + 19.2;
954     }                                             954     }
955     else                                          955     else
956     {                                             956     {
957       G4double ld  = logP - minLogP;              957       G4double ld  = logP - minLogP;
958       G4double ld2 = ld*ld;                       958       G4double ld2 = ld*ld;
959       G4double sp  = std::sqrt(pLab);             959       G4double sp  = std::sqrt(pLab);
960       G4double p2  = pLab*pLab;                   960       G4double p2  = pLab*pLab;
961       G4double p4  = p2*p2;                       961       G4double p4  = p2*p2;
962       G4double lm  = pLab - 0.94;                 962       G4double lm  = pLab - 0.94;
963       G4double md  = lm*lm + .392;                963       G4double md  = lm*lm + .392; 
964       fElasticXsc  = (cofLogE*ld2 + 2.23)/(1.     964       fElasticXsc  = (cofLogE*ld2 + 2.23)/(1. - .7/sp + .1/p4) + 2./md;
965       fTotalXsc    = (cofLogT*ld2 + 19.5)/(1.     965       fTotalXsc    = (cofLogT*ld2 + 19.5)/(1. + .46/sp + 1.6/p4) + 4.6/md;
966     }                                             966     }
967   }                                               967   }
968                                                   968 
969   fTotalXsc   *= CLHEP::millibarn;                969   fTotalXsc   *= CLHEP::millibarn; 
970   fElasticXsc *= CLHEP::millibarn;                970   fElasticXsc *= CLHEP::millibarn;
971                                                   971 
972   if( proton && theParticle->GetPDGCharge() >     972   if( proton && theParticle->GetPDGCharge() > 0. )
973   {                                               973   {
974     G4double cB = G4NuclearRadii::CoulombFacto    974     G4double cB = G4NuclearRadii::CoulombFactor(theParticle, nucleon, ekin);
975     fTotalXsc   *= cB;                            975     fTotalXsc   *= cB;
976     fElasticXsc *= cB;                            976     fElasticXsc *= cB; 
977   }                                               977   }
978   fElasticXsc = std::min(fElasticXsc, fTotalXs    978   fElasticXsc = std::min(fElasticXsc, fTotalXsc);
979   fInelasticXsc = std::max(fTotalXsc - fElasti    979   fInelasticXsc = std::max(fTotalXsc - fElasticXsc,0.0);
980   /*                                              980   /*
981   G4cout << "HNXscVG: E= " << ekin << " " << t    981   G4cout << "HNXscVG: E= " << ekin << " " << theParticle->GetParticleName() 
982    << " P: " << proton << " xtot(b)= " << fTot    982    << " P: " << proton << " xtot(b)= " << fTotalXsc/barn
983    << " xel(b)= " <<  fElasticXsc/barn << " xi    983    << " xel(b)= " <<  fElasticXsc/barn << " xinel(b)= " << fInelasticXsc/barn
984    << G4endl;                                     984    << G4endl;
985   */                                              985   */
986   return fTotalXsc;                               986   return fTotalXsc;
987 }                                                 987 }
988                                                   988 
989 //////////////////////////////////////////////    989 //////////////////////////////////////////////////////////////////////////////
990 //                                                990 //
991 // Returns hyperon-nucleon cross-section using    991 // Returns hyperon-nucleon cross-section using NS x-section for protons
992                                                   992 
993 G4double G4HadronNucleonXsc::HyperonNucleonXsc    993 G4double G4HadronNucleonXsc::HyperonNucleonXscNS(
994          const G4ParticleDefinition* thePartic    994          const G4ParticleDefinition* theParticle, 
995    const G4ParticleDefinition* nucleon, G4doub    995    const G4ParticleDefinition* nucleon, G4double ekin)
996 {                                                 996 {
997   G4double coeff = 1.0;                           997   G4double coeff = 1.0;
998   G4int pdg = std::abs(theParticle->GetPDGEnco    998   G4int pdg = std::abs(theParticle->GetPDGEncoding());
999                                                   999     
1000   // lambda, sigma+-0 and anti-hyperons          1000   // lambda, sigma+-0 and anti-hyperons
1001   if( pdg == 3122 || pdg == 3112 || pdg == 32    1001   if( pdg == 3122 || pdg == 3112 || pdg == 3212 || pdg == 3222 )
1002   {                                              1002   {
1003     coeff = 0.88;                                1003     coeff = 0.88;
1004   }                                              1004   } 
1005   // Xi hyperons and anti-hyperons               1005   // Xi hyperons and anti-hyperons
1006   else if( pdg == 3312 || pdg == 3322 )          1006   else if( pdg == 3312 || pdg == 3322 )
1007   {                                              1007   {
1008     coeff = 0.76;                                1008     coeff = 0.76;
1009   }                                              1009   }
1010   // omega, anti_omega                           1010   // omega, anti_omega
1011   else if( pdg == 3334 )                         1011   else if( pdg == 3334 )
1012   {                                              1012   {
1013     coeff = 0.64;                                1013     coeff = 0.64;
1014   }                                              1014   }
1015   // lambdaC, sigmaC+-0 and anti-hyperonsC       1015   // lambdaC, sigmaC+-0 and anti-hyperonsC
1016   else if( pdg == 4122 || pdg == 4112 || pdg     1016   else if( pdg == 4122 || pdg == 4112 || pdg == 4212 || pdg == 4222 ) 
1017   {                                              1017   {
1018     coeff = 0.784378;                            1018     coeff = 0.784378;
1019   }                                              1019   }
1020   // omegaC0, anti_omegaC0                       1020   // omegaC0, anti_omegaC0
1021   else if( pdg == 4332 )                         1021   else if( pdg == 4332 )
1022   {                                              1022   {
1023     coeff = 0.544378;                            1023     coeff = 0.544378;
1024   }                                              1024   }
1025   // XiC+0 and anti-hyperonC                     1025   // XiC+0 and anti-hyperonC
1026   else if( pdg == 4132 || pdg == 4232 )          1026   else if( pdg == 4132 || pdg == 4232 )
1027   {                                              1027   {
1028     coeff = 0.664378;                            1028     coeff = 0.664378;
1029   }                                              1029   }
1030   // lambdaB, sigmaB+-0 and anti-hyperonsB       1030   // lambdaB, sigmaB+-0 and anti-hyperonsB
1031   else if( pdg == 5122 || pdg == 5112 || pdg     1031   else if( pdg == 5122 || pdg == 5112 || pdg == 5212 || pdg == 5222 )
1032   {                                              1032   {
1033     coeff = 0.740659;                            1033     coeff = 0.740659;
1034   }                                              1034   }
1035   // omegaB0, anti_omegaB0                       1035   // omegaB0, anti_omegaB0
1036   else if( pdg == 5332 )                         1036   else if( pdg == 5332 )
1037   {                                              1037   {
1038     coeff = 0.500659;                            1038     coeff = 0.500659;
1039   }                                              1039   }
1040   // XiB+0 and anti-hyperonB                     1040   // XiB+0 and anti-hyperonB
1041   else if( pdg == 5132 || pdg == 5232 )          1041   else if( pdg == 5132 || pdg == 5232 )
1042   {                                              1042   {
1043     coeff = 0.620659;                            1043     coeff = 0.620659;
1044   }                                              1044   } 
1045   fTotalXsc = coeff*HadronNucleonXscNS( thePr    1045   fTotalXsc = coeff*HadronNucleonXscNS( theProton, nucleon, ekin);
1046   fInelasticXsc *= coeff;                        1046   fInelasticXsc *= coeff;
1047   fElasticXsc *= coeff;                          1047   fElasticXsc *= coeff;
1048                                                  1048   
1049   return fTotalXsc;                              1049   return fTotalXsc;
1050 }                                                1050 }
1051                                                  1051 
1052 /////////////////////////////////////////////    1052 //////////////////////////////////////////////////////////////////////////////
1053 //                                               1053 //
1054 // Returns hyperon-nucleon cross-section usin    1054 // Returns hyperon-nucleon cross-section using NS x-section for protons
1055                                                  1055 
1056 G4double G4HadronNucleonXsc::SCBMesonNucleonX    1056 G4double G4HadronNucleonXsc::SCBMesonNucleonXscNS( 
1057          const G4ParticleDefinition* theParti    1057          const G4ParticleDefinition* theParticle, 
1058          const G4ParticleDefinition* nucleon,    1058          const G4ParticleDefinition* nucleon, G4double ekin )
1059 {                                                1059 {
1060   G4double coeff(1.0);                           1060   G4double coeff(1.0);
1061   G4int pdg = std::abs(theParticle->GetPDGEnc    1061   G4int pdg = std::abs(theParticle->GetPDGEncoding());
1062                                                  1062 
1063   // B+-0 anti                                   1063   // B+-0 anti
1064   if( pdg == 511 || pdg == 521 )                 1064   if( pdg == 511 || pdg == 521 )
1065   {                                              1065   {
1066     coeff = 0.610989;                            1066     coeff = 0.610989;
1067   }                                              1067   }
1068   // D+-0 anti                                   1068   // D+-0 anti
1069   else if( pdg == 411 || pdg == 421 )            1069   else if( pdg == 411 || pdg == 421 )
1070   {                                              1070   {
1071     coeff = 0.676568;                            1071     coeff = 0.676568;
1072   }                                              1072   }
1073   // Bs, antiBs                                  1073   // Bs, antiBs
1074   else if( pdg == 531 )                          1074   else if( pdg == 531 )
1075   {                                              1075   {
1076     coeff = 0.430989;                            1076     coeff = 0.430989;
1077   }                                              1077   }
1078   // Bc+-                                        1078   // Bc+-
1079   else if( pdg == 541 )                          1079   else if( pdg == 541 )
1080   {                                              1080   {
1081     coeff = 0.287557;                            1081     coeff = 0.287557;
1082   }                                              1082   }
1083   // Ds+-                                        1083   // Ds+-
1084   else if( pdg == 431 )                          1084   else if( pdg == 431 )
1085   {                                              1085   {
1086     coeff = 0.496568;                            1086     coeff = 0.496568;
1087   }                                              1087   }
1088   // etaC, J/Psi                                 1088   // etaC, J/Psi
1089   else if( pdg == 441 || pdg == 443 )            1089   else if( pdg == 441 || pdg == 443 )
1090   {                                              1090   {
1091     coeff = 0.353135;                            1091     coeff = 0.353135;
1092   }                                              1092   }
1093   // Upsilon                                     1093   // Upsilon
1094   else if( pdg == 553 )                          1094   else if( pdg == 553 )
1095   {                                              1095   {
1096     coeff = 0.221978;                            1096     coeff = 0.221978;
1097   }                                              1097   }
1098   // eta                                         1098   // eta
1099   else if( pdg == 221 )                          1099   else if( pdg == 221 )
1100   {                                              1100   {
1101     coeff = 0.76;                                1101     coeff = 0.76;
1102   }                                              1102   }
1103   // eta'                                        1103   // eta'
1104   else if( pdg == 331 )                          1104   else if( pdg == 331 )
1105   {                                              1105   {
1106     coeff = 0.88;                                1106     coeff = 0.88;
1107   }                                              1107   }
1108   fTotalXsc = coeff*HadronNucleonXscNS(thePiP    1108   fTotalXsc = coeff*HadronNucleonXscNS(thePiPlus, nucleon, ekin);
1109   fElasticXsc *= coeff;                          1109   fElasticXsc *= coeff;
1110   fInelasticXsc *= coeff;                        1110   fInelasticXsc *= coeff;
1111   return fTotalXsc;                              1111   return fTotalXsc;
1112 }                                                1112 }
1113 /////////////////////////////////////////////    1113 ////////////////////////////////////////////////////////////////////////////////
1114 //                                               1114 //
1115 // Returns hadron-nucleon cross-section based    1115 // Returns hadron-nucleon cross-section based on V. Uzjinsky parametrisation of
1116 // data from G4FTFCrossSection class             1116 // data from G4FTFCrossSection class
1117                                                  1117 
1118 G4double G4HadronNucleonXsc::HadronNucleonXsc    1118 G4double G4HadronNucleonXsc::HadronNucleonXscVU(
1119                              const G4Particle    1119                              const G4ParticleDefinition* theParticle, 
1120            const G4ParticleDefinition* nucleo    1120            const G4ParticleDefinition* nucleon, G4double ekin)
1121 {                                                1121 {
1122   G4int PDGcode = theParticle->GetPDGEncoding    1122   G4int PDGcode = theParticle->GetPDGEncoding();
1123   G4int absPDGcode = std::abs(PDGcode);          1123   G4int absPDGcode = std::abs(PDGcode);
1124   G4double mass = theParticle->GetPDGMass();     1124   G4double mass = theParticle->GetPDGMass();
1125   G4double Plab = std::sqrt(ekin*(ekin + 2.*m << 1125   G4double Elab = ekin + mass;              
                                                   >> 1126   // (s - 2*0.88*GeV*GeV)/(2*0.939*GeV)/GeV;
                                                   >> 1127   G4double Plab = std::sqrt(ekin*(ekin + 2.*mass));            
                                                   >> 1128 
                                                   >> 1129   Elab *= invGeV;
                                                   >> 1130   Plab *= invGeV;
1126                                                  1131 
1127   G4double logPlab = G4Log( Plab );              1132   G4double logPlab = G4Log( Plab );
1128   G4double sqrLogPlab = logPlab * logPlab;       1133   G4double sqrLogPlab = logPlab * logPlab;
1129                                                  1134 
1130   G4bool proton = (nucleon == theProton);        1135   G4bool proton = (nucleon == theProton);
1131   G4bool neutron = (nucleon == theNeutron);      1136   G4bool neutron = (nucleon == theNeutron);
1132                                                  1137    
1133   if( absPDGcode > 1000)  //------Projectile     1138   if( absPDGcode > 1000)  //------Projectile is baryon -
1134   {                                              1139   {
1135     if(proton)                                   1140     if(proton)
1136     {                                            1141     {
1137       fTotalXsc   = 48.0 + 0.522*sqrLogPlab -    1142       fTotalXsc   = 48.0 + 0.522*sqrLogPlab - 4.51*logPlab;
1138       fElasticXsc = 11.9 + 26.9*G4Exp(-logPla    1143       fElasticXsc = 11.9 + 26.9*G4Exp(-logPlab*1.21) + 0.169*sqrLogPlab - 1.85*logPlab;
1139     }                                            1144     }
1140     if(neutron)                                  1145     if(neutron)
1141     {                                            1146     {    
1142       fTotalXsc   = 47.3  + 0.513*sqrLogPlab     1147       fTotalXsc   = 47.3  + 0.513*sqrLogPlab - 4.27*logPlab;
1143       fElasticXsc = 11.9 + 26.9*G4Exp(-logPla    1148       fElasticXsc = 11.9 + 26.9*G4Exp(-logPlab*1.21) + 0.169*sqrLogPlab - 1.85*logPlab;
1144     }                                            1149     }
1145   }                                              1150   }
1146   else if( PDGcode ==  211)  //------Projecti    1151   else if( PDGcode ==  211)  //------Projectile is PionPlus ----
1147   {                                              1152   {
1148     if(proton)                                   1153     if(proton)
1149     {                                            1154     {
1150       fTotalXsc  = 16.4 + 19.3 *G4Exp(-logPla    1155       fTotalXsc  = 16.4 + 19.3 *G4Exp(-logPlab*0.42) + 0.19 *sqrLogPlab - 0.0 *logPlab;
1151       fElasticXsc =  0.0 + 11.4*G4Exp(-logPla    1156       fElasticXsc =  0.0 + 11.4*G4Exp(-logPlab*0.40) + 0.079*sqrLogPlab - 0.0 *logPlab;
1152     }                                            1157     }
1153     if(neutron)                                  1158     if(neutron)
1154     {                                            1159     {    
1155       fTotalXsc   =  33.0 + 14.0 *G4Exp(-logP    1160       fTotalXsc   =  33.0 + 14.0 *G4Exp(-logPlab*1.36) + 0.456*sqrLogPlab - 4.03*logPlab;
1156       fElasticXsc = 1.76 + 11.2*G4Exp(-logPla    1161       fElasticXsc = 1.76 + 11.2*G4Exp(-logPlab*0.64) + 0.043*sqrLogPlab - 0.0 *logPlab;
1157     }                                            1162     }
1158   }                                              1163   }
1159   else if( PDGcode == -211)  //------Projecti    1164   else if( PDGcode == -211)  //------Projectile is PionMinus ----
1160   {                                              1165   {
1161     if(proton)                                   1166     if(proton)
1162     {                                            1167     {
1163       fTotalXsc   = 33.0 + 14.0 *G4Exp(-logPl    1168       fTotalXsc   = 33.0 + 14.0 *G4Exp(-logPlab*1.36) + 0.456*sqrLogPlab - 4.03*logPlab;
1164       fElasticXsc = 1.76 + 11.2*G4Exp(-logPla    1169       fElasticXsc = 1.76 + 11.2*G4Exp(-logPlab*0.64) + 0.043*sqrLogPlab - 0.0 *logPlab;
1165     }                                            1170     }
1166     if(neutron)                                  1171     if(neutron)
1167     {                                            1172     {    
1168       fTotalXsc   = 16.4 + 19.3 *G4Exp(-logPl    1173       fTotalXsc   = 16.4 + 19.3 *G4Exp(-logPlab*0.42) + 0.19 *sqrLogPlab - 0.0 *logPlab;
1169       fElasticXsc =  0.0 + 11.4*G4Exp(-logPla    1174       fElasticXsc =  0.0 + 11.4*G4Exp(-logPlab*0.40) + 0.079*sqrLogPlab - 0.0 *logPlab;
1170     }                                            1175     }
1171   }                                              1176   }
1172   else if( PDGcode ==  111)  //------Projecti    1177   else if( PDGcode ==  111)  //------Projectile is PionZero  --
1173   {                                              1178   {
1174     if(proton)                                   1179     if(proton)
1175     {                                            1180     {
1176       fTotalXsc = (16.4 + 19.3 *G4Exp(-logPla    1181       fTotalXsc = (16.4 + 19.3 *G4Exp(-logPlab*0.42) + 0.19 *sqrLogPlab - 0.0 *logPlab +   //Pi+
1177        33.0 + 14.0 *G4Exp(-logPlab*1.36) + 0.    1182        33.0 + 14.0 *G4Exp(-logPlab*1.36) + 0.456*sqrLogPlab - 4.03*logPlab)/2; //Pi-
1178                                                  1183 
1179       fElasticXsc = (0.0 + 11.4*G4Exp(-logPla    1184       fElasticXsc = (0.0 + 11.4*G4Exp(-logPlab*0.40) + 0.079*sqrLogPlab - 0.0 *logPlab +   //Pi+
1180          1.76 + 11.2*G4Exp(-logPlab*0.64) + 0    1185          1.76 + 11.2*G4Exp(-logPlab*0.64) + 0.043*sqrLogPlab - 0.0 *logPlab)/2;//Pi-
1181                                                  1186 
1182     }                                            1187     }
1183     if(neutron)                                  1188     if(neutron)
1184     {                                            1189     {    
1185       fTotalXsc = (33.0 + 14.0 *G4Exp(-logPla    1190       fTotalXsc = (33.0 + 14.0 *G4Exp(-logPlab*1.36) + 0.456*sqrLogPlab - 4.03*logPlab +   //Pi+
1186        16.4 + 19.3 *G4Exp(-logPlab*0.42) + 0.    1191        16.4 + 19.3 *G4Exp(-logPlab*0.42) + 0.19 *sqrLogPlab - 0.0 *logPlab)/2; //Pi-
1187       fElasticXsc = (1.76 + 11.2*G4Exp(-logPl    1192       fElasticXsc = (1.76 + 11.2*G4Exp(-logPlab*0.64) + 0.043*sqrLogPlab - 0.0 *logPlab +  //Pi+
1188          0.0  + 11.4*G4Exp(-logPlab*0.40) + 0    1193          0.0  + 11.4*G4Exp(-logPlab*0.40) + 0.079*sqrLogPlab - 0.0 *logPlab)/2;//Pi-
1189     }                                            1194     }
1190   }                                              1195   }
1191   else if( PDGcode == 321 )    //------Projec    1196   else if( PDGcode == 321 )    //------Projectile is KaonPlus --
1192   {                                              1197   {
1193     if(proton)                                   1198     if(proton)
1194     {                                            1199     {
1195       fTotalXsc   = 18.1 +  0.26 *sqrLogPlab     1200       fTotalXsc   = 18.1 +  0.26 *sqrLogPlab - 1.0 *logPlab;
1196       fElasticXsc =  5.0 +  8.1*G4Exp(-logPla    1201       fElasticXsc =  5.0 +  8.1*G4Exp(-logPlab*1.8 ) + 0.16 *sqrLogPlab - 1.3 *logPlab;
1197     }                                            1202     }
1198     if(neutron)                                  1203     if(neutron)
1199     {                                            1204     {    
1200       fTotalXsc   = 18.7  + 0.21 *sqrLogPlab     1205       fTotalXsc   = 18.7  + 0.21 *sqrLogPlab - 0.89*logPlab;
1201       fElasticXsc =  7.3  + 0.29 *sqrLogPlab     1206       fElasticXsc =  7.3  + 0.29 *sqrLogPlab - 2.4 *logPlab;
1202     }                                            1207     }
1203   }                                              1208   }
1204   else if( PDGcode ==-321 )  //------Projecti    1209   else if( PDGcode ==-321 )  //------Projectile is KaonMinus ----
1205   {                                              1210   {
1206     if(proton)                                   1211     if(proton)
1207     {                                            1212     {
1208       fTotalXsc   = 32.1 + 0.66*sqrLogPlab -     1213       fTotalXsc   = 32.1 + 0.66*sqrLogPlab - 5.6*logPlab;
1209       fElasticXsc =  7.3 + 0.29*sqrLogPlab -     1214       fElasticXsc =  7.3 + 0.29*sqrLogPlab - 2.4*logPlab;
1210     }                                            1215     }
1211     if(neutron)                                  1216     if(neutron)
1212     {                                            1217     {    
1213       fTotalXsc   = 25.2 + 0.38*sqrLogPlab -     1218       fTotalXsc   = 25.2 + 0.38*sqrLogPlab - 2.9*logPlab;
1214       fElasticXsc =  5.0 +  8.1*G4Exp(-logPla    1219       fElasticXsc =  5.0 +  8.1*G4Exp(-logPlab*1.8 ) + 0.16*sqrLogPlab - 1.3*logPlab;
1215     }                                            1220     }
1216   }                                              1221   }
1217   else if( PDGcode == 311 )  //------Projecti    1222   else if( PDGcode == 311 )  //------Projectile is KaonZero -----
1218   {                                              1223   {
1219     if(proton)                                   1224     if(proton)
1220     {                                            1225     {
1221       fTotalXsc   = ( 18.1 + 0.26 *sqrLogPlab    1226       fTotalXsc   = ( 18.1 + 0.26 *sqrLogPlab - 1.0 *logPlab +   //K+
1222                       32.1 + 0.66 *sqrLogPlab    1227                       32.1 + 0.66 *sqrLogPlab - 5.6 *logPlab)/2; //K-
1223       fElasticXsc = (  5.0 +  8.1*G4Exp(-logP    1228       fElasticXsc = (  5.0 +  8.1*G4Exp(-logPlab*1.8 ) + 0.16 *sqrLogPlab - 1.3 *logPlab + //K+
1224                          7.3 + 0.29 *sqrLogPl    1229                          7.3 + 0.29 *sqrLogPlab - 2.4 *logPlab)/2; //K-
1225     }                                            1230     }
1226     if(neutron)                                  1231     if(neutron)
1227     {                                            1232     {    
1228       fTotalXsc   = ( 18.7 + 0.21 *sqrLogPlab    1233       fTotalXsc   = ( 18.7 + 0.21 *sqrLogPlab - 0.89*logPlab +   //K+
1229                       25.2 + 0.38 *sqrLogPlab    1234                       25.2 + 0.38 *sqrLogPlab - 2.9 *logPlab)/2; //K-
1230       fElasticXsc = (  7.3 + 0.29 *sqrLogPlab    1235       fElasticXsc = (  7.3 + 0.29 *sqrLogPlab - 2.4 *logPlab +   //K+
1231                        5.0 + 8.1*G4Exp(-logPl    1236                        5.0 + 8.1*G4Exp(-logPlab*1.8 ) + 0.16 *sqrLogPlab - 1.3 *logPlab)/2; //K-
1232     }                                            1237     }
1233   }                                              1238   }
1234   else  //------Projectile is undefined, Nucl    1239   else  //------Projectile is undefined, Nucleon assumed
1235   {                                              1240   {
1236     if(proton)                                   1241     if(proton)
1237     {                                            1242     {
1238       fTotalXsc   = 48.0 + 0.522*sqrLogPlab -    1243       fTotalXsc   = 48.0 + 0.522*sqrLogPlab - 4.51*logPlab;
1239       fElasticXsc = 11.9 + 26.9*G4Exp(-logPla    1244       fElasticXsc = 11.9 + 26.9*G4Exp(-logPlab*1.21) + 0.169*sqrLogPlab - 1.85*logPlab;
1240     }                                            1245     }
1241     if(neutron)                                  1246     if(neutron)
1242     {                                            1247     {    
1243       fTotalXsc   = 47.3 + 0.513*sqrLogPlab -    1248       fTotalXsc   = 47.3 + 0.513*sqrLogPlab - 4.27*logPlab;
1244       fElasticXsc = 11.9 + 26.9*G4Exp(-logPla    1249       fElasticXsc = 11.9 + 26.9*G4Exp(-logPlab*1.21) + 0.169*sqrLogPlab - 1.85*logPlab;
1245     }                                            1250     }
1246   }                                              1251   }
1247                                                  1252 
1248   fTotalXsc   *= CLHEP::millibarn;               1253   fTotalXsc   *= CLHEP::millibarn;
1249   fElasticXsc *= CLHEP::millibarn;               1254   fElasticXsc *= CLHEP::millibarn;
1250   fElasticXsc = std::min(fElasticXsc, fTotalX    1255   fElasticXsc = std::min(fElasticXsc, fTotalXsc);
1251   fInelasticXsc = fTotalXsc - fElasticXsc;       1256   fInelasticXsc = fTotalXsc - fElasticXsc;
1252                                                  1257 
1253   return fTotalXsc;                              1258   return fTotalXsc;    
1254 }                                                1259 }
1255                                                  1260 
1256 /////////////////////////////////////////////    1261 //////////////////////////////////////////////////////////////////////////////
1257 //                                               1262 //
1258 // Returns hadron-nucleon Xsc according to di    1263 // Returns hadron-nucleon Xsc according to different parametrisations:
1259 // [2] E. Levin, hep-ph/9710546                  1264 // [2] E. Levin, hep-ph/9710546
1260 // [3] U. Dersch, et al, hep-ex/9910052          1265 // [3] U. Dersch, et al, hep-ex/9910052
1261 // [4] M.J. Longo, et al, Phys.Rev.Lett. 33 (    1266 // [4] M.J. Longo, et al, Phys.Rev.Lett. 33 (1974) 725 
1262                                                  1267 
1263 G4double G4HadronNucleonXsc::HadronNucleonXsc    1268 G4double G4HadronNucleonXsc::HadronNucleonXscEL(
1264                              const G4Particle    1269                              const G4ParticleDefinition* theParticle, 
1265            const G4ParticleDefinition*, G4dou    1270            const G4ParticleDefinition*, G4double ekin)
1266 {                                                1271 {
1267   G4int pdg = theParticle->GetPDGEncoding();     1272   G4int pdg = theParticle->GetPDGEncoding();
1268   G4double xsection(0.);                         1273   G4double xsection(0.);
1269   static const G4double targ_mass =              1274   static const G4double targ_mass = 
1270     0.5*(CLHEP::proton_mass_c2 + CLHEP::neutr    1275     0.5*(CLHEP::proton_mass_c2 + CLHEP::neutron_mass_c2);
1271   G4double sMand =                               1276   G4double sMand = 
1272     CalcMandelstamS(ekin, theParticle->GetPDG    1277     CalcMandelstamS(ekin, theParticle->GetPDGMass(), targ_mass)*invGeV2;
1273                                                  1278 
1274   G4double x1 = G4Exp(G4Log(sMand)*0.0808);      1279   G4double x1 = G4Exp(G4Log(sMand)*0.0808);
1275   G4double x2 = G4Exp(G4Log(-sMand)*0.4525);     1280   G4double x2 = G4Exp(G4Log(-sMand)*0.4525);
1276                                                  1281 
1277   if(pdg == 22)                                  1282   if(pdg == 22) 
1278   {                                              1283   {
1279     xsection = 0.0677*x1 + 0.129*x2;             1284     xsection = 0.0677*x1 + 0.129*x2;
1280   }                                              1285   } 
1281   else if(theParticle == theNeutron)             1286   else if(theParticle == theNeutron)  
1282   {                                              1287   {
1283     xsection = 21.70*x1 + 56.08*x2;              1288     xsection = 21.70*x1 + 56.08*x2;
1284   }                                              1289   } 
1285   else if(theParticle == theProton)              1290   else if(theParticle == theProton) 
1286   {                                              1291   {
1287     xsection = 21.70*x1 + 56.08*x2;              1292     xsection = 21.70*x1 + 56.08*x2;
1288   }                                              1293   } 
1289   // pbar                                        1294   // pbar
1290   else if(pdg == -2212)                          1295   else if(pdg == -2212) 
1291   {                                              1296   {
1292     xsection = 21.70*x1 + 98.39*x2;              1297     xsection = 21.70*x1 + 98.39*x2;
1293   }                                              1298   } 
1294   else if(theParticle == thePiPlus)              1299   else if(theParticle == thePiPlus) 
1295   {                                              1300   {
1296     xsection = 13.63*x1 + 27.56*x2;              1301     xsection = 13.63*x1 + 27.56*x2;
1297   }                                              1302   } 
1298   // pi-                                         1303   // pi-
1299   else if(pdg == -211)                           1304   else if(pdg == -211) 
1300   {                                              1305   {
1301     xsection = 13.63*x1 + 36.02*x2;              1306     xsection = 13.63*x1 + 36.02*x2;
1302   }                                              1307   } 
1303   else if(theParticle == theKPlus)               1308   else if(theParticle == theKPlus) 
1304   {                                              1309   {
1305     xsection = 11.82*x1 + 8.15*x2;               1310     xsection = 11.82*x1 + 8.15*x2;
1306   }                                              1311   } 
1307   else if(theParticle == theKMinus)              1312   else if(theParticle == theKMinus) 
1308   {                                              1313   {
1309     xsection = 11.82*x1 + 26.36*x2;              1314     xsection = 11.82*x1 + 26.36*x2;
1310   }                                              1315   }
1311   else if(theParticle == theK0S || theParticl    1316   else if(theParticle == theK0S || theParticle == theK0L) 
1312   {                                              1317   {
1313     xsection = 11.82*x1 + 17.25*x2;              1318     xsection = 11.82*x1 + 17.25*x2;
1314   }                                              1319   }
1315   else                                           1320   else  
1316   {                                              1321   {
1317     xsection = 21.70*x1 + 56.08*x2;              1322     xsection = 21.70*x1 + 56.08*x2;
1318   }                                              1323   }
1319   fTotalXsc     = xsection*CLHEP::millibarn;     1324   fTotalXsc     = xsection*CLHEP::millibarn;
1320   fInelasticXsc = 0.83*fTotalXsc;                1325   fInelasticXsc = 0.83*fTotalXsc;
1321   fElasticXsc   = fTotalXsc - fInelasticXsc;     1326   fElasticXsc   = fTotalXsc - fInelasticXsc;
1322   return fTotalXsc;                              1327   return fTotalXsc;
1323 }                                                1328 }
1324                                                  1329 
1325 /////////////////////////////////////////////    1330 ///////////////////////////////////////////////////////////////////////////////
1326                                                  1331 
1327 G4double                                         1332 G4double 
1328 G4HadronNucleonXsc::CoulombBarrier(const G4Pa    1333 G4HadronNucleonXsc::CoulombBarrier(const G4ParticleDefinition* theParticle, 
1329            const G4ParticleDefinition* nucleo    1334            const G4ParticleDefinition* nucleon, 
1330            G4double ekin)                        1335            G4double ekin)
1331 {                                                1336 {
1332   G4double tR = 0.895*CLHEP::fermi;              1337   G4double tR = 0.895*CLHEP::fermi;
1333   G4double pR = 0.5*CLHEP::fermi;                1338   G4double pR = 0.5*CLHEP::fermi;
1334                                                  1339 
1335   if     ( theParticle == theProton ) pR = 0.    1340   if     ( theParticle == theProton ) pR = 0.895*CLHEP::fermi;
1336   else if( theParticle == thePiPlus ) pR = 0.    1341   else if( theParticle == thePiPlus ) pR = 0.663*CLHEP::fermi;
1337   else if( theParticle == theKPlus )  pR = 0.    1342   else if( theParticle == theKPlus )  pR = 0.340*CLHEP::fermi;
1338                                                  1343 
1339   G4double pZ = theParticle->GetPDGCharge();     1344   G4double pZ = theParticle->GetPDGCharge();
1340   G4double tZ = nucleon->GetPDGCharge();         1345   G4double tZ = nucleon->GetPDGCharge();
1341                                                  1346 
1342   G4double pM = theParticle->GetPDGMass();       1347   G4double pM = theParticle->GetPDGMass(); 
1343   G4double tM = nucleon->GetPDGMass();           1348   G4double tM = nucleon->GetPDGMass();
1344                                                  1349 
1345   G4double pElab = ekin + pM;                    1350   G4double pElab = ekin + pM;
1346                                                  1351 
1347   G4double totEcm  = std::sqrt(pM*pM + tM*tM     1352   G4double totEcm  = std::sqrt(pM*pM + tM*tM + 2.*pElab*tM);
1348                                                  1353 
1349   G4double totTcm  = totEcm - pM -tM;            1354   G4double totTcm  = totEcm - pM -tM;
1350                                                  1355 
1351   G4double bC = fine_structure_const*hbarc*pZ    1356   G4double bC = fine_structure_const*hbarc*pZ*tZ/(2.*(pR + tR));
1352                                                  1357 
1353   //G4cout<<"##CB: ekin = "<<ekin<<"; pElab=     1358   //G4cout<<"##CB: ekin = "<<ekin<<"; pElab= " << pElab
1354   //  <<"; bC = "<<bC<<"; Tcm = "<< totTcm <<    1359   //  <<"; bC = "<<bC<<"; Tcm = "<< totTcm <<G4endl;
1355                                                  1360 
1356   G4double ratio = (totTcm > bC) ? 1. - bC/to    1361   G4double ratio = (totTcm > bC) ? 1. - bC/totTcm : 0.0;
1357                                                  1362 
1358   // G4cout <<"ratio = "<<ratio<<G4endl;         1363   // G4cout <<"ratio = "<<ratio<<G4endl;
1359   return ratio;                                  1364   return ratio;
1360 }                                                1365 }
1361                                                  1366 
1362 /////////////////////////////////////////////    1367 //////////////////////////////////////////////////////////////////////////////
1363                                                  1368