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Geant4/processes/hadronic/models/coherent_elastic/src/G4NuclNuclDiffuseElastic.cc

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Differences between /processes/hadronic/models/coherent_elastic/src/G4NuclNuclDiffuseElastic.cc (Version 11.3.0) and /processes/hadronic/models/coherent_elastic/src/G4NuclNuclDiffuseElastic.cc (Version 10.7.p1)


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 25 //                                                 25 //
 26 //                                                 26 //
 27 //                                                 27 //
 28 // Physics model class G4NuclNuclDiffuseElasti     28 // Physics model class G4NuclNuclDiffuseElastic 
 29 //                                                 29 //
 30 //                                                 30 //
 31 // G4 Model: optical diffuse elastic scatterin     31 // G4 Model: optical diffuse elastic scattering with 4-momentum balance
 32 //                                                 32 //                         
 33 // 24-May-07 V. Grichine                           33 // 24-May-07 V. Grichine
 34 //                                                 34 //
 35                                                    35 
 36 #include "G4NuclNuclDiffuseElastic.hh"             36 #include "G4NuclNuclDiffuseElastic.hh"
 37 #include "G4ParticleTable.hh"                      37 #include "G4ParticleTable.hh"
 38 #include "G4ParticleDefinition.hh"                 38 #include "G4ParticleDefinition.hh"
 39 #include "G4IonTable.hh"                           39 #include "G4IonTable.hh"
 40 #include "G4NucleiProperties.hh"                   40 #include "G4NucleiProperties.hh"
 41                                                    41 
 42 #include "Randomize.hh"                            42 #include "Randomize.hh"
 43 #include "G4Integrator.hh"                         43 #include "G4Integrator.hh"
 44 #include "globals.hh"                              44 #include "globals.hh"
 45 #include "G4PhysicalConstants.hh"                  45 #include "G4PhysicalConstants.hh"
 46 #include "G4SystemOfUnits.hh"                      46 #include "G4SystemOfUnits.hh"
 47                                                    47 
 48 #include "G4Proton.hh"                             48 #include "G4Proton.hh"
 49 #include "G4Neutron.hh"                            49 #include "G4Neutron.hh"
 50 #include "G4Deuteron.hh"                           50 #include "G4Deuteron.hh"
 51 #include "G4Alpha.hh"                              51 #include "G4Alpha.hh"
 52 #include "G4PionPlus.hh"                           52 #include "G4PionPlus.hh"
 53 #include "G4PionMinus.hh"                          53 #include "G4PionMinus.hh"
 54                                                    54 
 55 #include "G4Element.hh"                            55 #include "G4Element.hh"
 56 #include "G4ElementTable.hh"                       56 #include "G4ElementTable.hh"
 57 #include "G4NistManager.hh"                        57 #include "G4NistManager.hh"
 58 #include "G4PhysicsTable.hh"                       58 #include "G4PhysicsTable.hh"
 59 #include "G4PhysicsLogVector.hh"                   59 #include "G4PhysicsLogVector.hh"
 60 #include "G4PhysicsFreeVector.hh"                  60 #include "G4PhysicsFreeVector.hh"
 61 #include "G4HadronicParameters.hh"                 61 #include "G4HadronicParameters.hh"
 62                                                    62 
 63 //////////////////////////////////////////////     63 /////////////////////////////////////////////////////////////////////////
 64 //                                                 64 //
 65 // Test Constructor. Just to check xsc             65 // Test Constructor. Just to check xsc
 66                                                    66 
 67                                                    67 
 68 G4NuclNuclDiffuseElastic::G4NuclNuclDiffuseEla     68 G4NuclNuclDiffuseElastic::G4NuclNuclDiffuseElastic() 
 69   : G4HadronElastic("NNDiffuseElastic"), fPart     69   : G4HadronElastic("NNDiffuseElastic"), fParticle(0)
 70 {                                                  70 {
 71   SetMinEnergy( 50*MeV );                          71   SetMinEnergy( 50*MeV );
 72   SetMaxEnergy( G4HadronicParameters::Instance     72   SetMaxEnergy( G4HadronicParameters::Instance()->GetMaxEnergy() );
 73   verboseLevel = 0;                                73   verboseLevel = 0;
 74   lowEnergyRecoilLimit = 100.*keV;                 74   lowEnergyRecoilLimit = 100.*keV;  
 75   lowEnergyLimitQ  = 0.0*GeV;                      75   lowEnergyLimitQ  = 0.0*GeV;  
 76   lowEnergyLimitHE = 0.0*GeV;                      76   lowEnergyLimitHE = 0.0*GeV;  
 77   lowestEnergyLimit= 0.0*keV;                      77   lowestEnergyLimit= 0.0*keV;  
 78   plabLowLimit     = 20.0*MeV;                     78   plabLowLimit     = 20.0*MeV;
 79                                                    79 
 80   theProton   = G4Proton::Proton();                80   theProton   = G4Proton::Proton();
 81   theNeutron  = G4Neutron::Neutron();              81   theNeutron  = G4Neutron::Neutron();
 82   theDeuteron = G4Deuteron::Deuteron();            82   theDeuteron = G4Deuteron::Deuteron();
 83   theAlpha    = G4Alpha::Alpha();                  83   theAlpha    = G4Alpha::Alpha();
 84   thePionPlus = G4PionPlus::PionPlus();            84   thePionPlus = G4PionPlus::PionPlus();
 85   thePionMinus= G4PionMinus::PionMinus();          85   thePionMinus= G4PionMinus::PionMinus();
 86                                                    86 
 87   fEnergyBin = 300;  // Increased from the ori     87   fEnergyBin = 300;  // Increased from the original 200 to have no wider log-energy-bins up to 10 PeV 
 88   fAngleBin  = 200;                                88   fAngleBin  = 200;
 89                                                    89 
 90   fEnergyVector =  new G4PhysicsLogVector( the     90   fEnergyVector =  new G4PhysicsLogVector( theMinEnergy, theMaxEnergy, fEnergyBin );
 91   fAngleTable = 0;                                 91   fAngleTable = 0;
 92                                                    92 
 93   fParticle = 0;                                   93   fParticle = 0;
 94   fWaveVector = 0.;                                94   fWaveVector = 0.;
 95   fAtomicWeight = 0.;                              95   fAtomicWeight = 0.;
 96   fAtomicNumber = 0.;                              96   fAtomicNumber = 0.;
 97   fNuclearRadius = 0.;                             97   fNuclearRadius = 0.;
 98   fBeta = 0.;                                      98   fBeta = 0.;
 99   fZommerfeld = 0.;                                99   fZommerfeld = 0.;
100   fAm = 0.;                                       100   fAm = 0.;
101   fAddCoulomb = false;                            101   fAddCoulomb = false;
102   // Ranges of angle table relative to current    102   // Ranges of angle table relative to current Rutherford (Coulomb grazing) angle
103                                                   103 
104   // Empirical parameters                         104   // Empirical parameters
105                                                   105 
106   fCofAlphaMax     = 1.5;                         106   fCofAlphaMax     = 1.5;
107   fCofAlphaCoulomb = 0.5;                         107   fCofAlphaCoulomb = 0.5;
108                                                   108 
109   fProfileDelta  = 1.;                            109   fProfileDelta  = 1.;
110   fProfileAlpha  = 0.5;                           110   fProfileAlpha  = 0.5;
111                                                   111 
112   fCofLambda = 1.0;                               112   fCofLambda = 1.0;
113   fCofDelta  = 0.04;                              113   fCofDelta  = 0.04;
114   fCofAlpha  = 0.095;                             114   fCofAlpha  = 0.095;
115                                                   115 
116   fNuclearRadius1 = fNuclearRadius2 = fNuclear    116   fNuclearRadius1 = fNuclearRadius2 = fNuclearRadiusSquare 
117     = fRutherfordRatio = fCoulombPhase0 = fHal    117     = fRutherfordRatio = fCoulombPhase0 = fHalfRutThetaTg = fHalfRutThetaTg2 
118     = fRutherfordTheta = fProfileLambda = fCof    118     = fRutherfordTheta = fProfileLambda = fCofPhase = fCofFar
119     = fSumSigma = fEtaRatio = fReZ = 0.0;         119     = fSumSigma = fEtaRatio = fReZ = 0.0;
120   fMaxL = 0;                                      120   fMaxL = 0;
121                                                   121 
122   fNuclearRadiusCof = 1.0;                        122   fNuclearRadiusCof = 1.0;
123   fCoulombMuC = 0.0;                              123   fCoulombMuC = 0.0;
124 }                                                 124 }
125                                                   125 
126 //////////////////////////////////////////////    126 //////////////////////////////////////////////////////////////////////////////
127 //                                                127 //
128 // Destructor                                     128 // Destructor
129                                                   129 
130 G4NuclNuclDiffuseElastic::~G4NuclNuclDiffuseEl    130 G4NuclNuclDiffuseElastic::~G4NuclNuclDiffuseElastic()
131 {                                                 131 {
132   if ( fEnergyVector ) {                          132   if ( fEnergyVector ) {
133     delete fEnergyVector;                         133     delete fEnergyVector;
134     fEnergyVector = 0;                            134     fEnergyVector = 0;
135   }                                               135   }
136                                                   136 
137   for ( std::vector<G4PhysicsTable*>::iterator    137   for ( std::vector<G4PhysicsTable*>::iterator it = fAngleBank.begin();
138         it != fAngleBank.end(); ++it ) {          138         it != fAngleBank.end(); ++it ) {
139     if ( (*it) ) (*it)->clearAndDestroy();        139     if ( (*it) ) (*it)->clearAndDestroy();
140     delete *it;                                   140     delete *it;
141     *it = 0;                                      141     *it = 0;
142   }                                               142   }
143   fAngleTable = 0;                                143   fAngleTable = 0;
144 }                                                 144 }
145                                                   145 
146 //////////////////////////////////////////////    146 //////////////////////////////////////////////////////////////////////////////
147 //                                                147 //
148 // Initialisation for given particle using ele    148 // Initialisation for given particle using element table of application
149                                                   149 
150 void G4NuclNuclDiffuseElastic::Initialise()       150 void G4NuclNuclDiffuseElastic::Initialise() 
151 {                                                 151 {
152                                                   152 
153   // fEnergyVector = new G4PhysicsLogVector( t    153   // fEnergyVector = new G4PhysicsLogVector( theMinEnergy, theMaxEnergy, fEnergyBin );
154                                                   154 
155   const G4ElementTable* theElementTable = G4El    155   const G4ElementTable* theElementTable = G4Element::GetElementTable();
156   std::size_t jEl, numOfEl = G4Element::GetNum << 156   size_t jEl, numOfEl = G4Element::GetNumberOfElements();
157                                                   157 
158   // projectile radius                            158   // projectile radius
159                                                   159 
160   G4double A1 = G4double( fParticle->GetBaryon    160   G4double A1 = G4double( fParticle->GetBaryonNumber() );
161   G4double R1 = CalculateNuclearRad(A1);          161   G4double R1 = CalculateNuclearRad(A1);
162                                                   162 
163   for(jEl = 0 ; jEl < numOfEl; ++jEl) // appli    163   for(jEl = 0 ; jEl < numOfEl; ++jEl) // application element loop
164   {                                               164   {
165     fAtomicNumber = (*theElementTable)[jEl]->G    165     fAtomicNumber = (*theElementTable)[jEl]->GetZ();     // atomic number
166     fAtomicWeight = G4NistManager::Instance()-    166     fAtomicWeight = G4NistManager::Instance()->GetAtomicMassAmu( static_cast< G4int >( fAtomicNumber ) );
167                                                   167 
168     fNuclearRadius = CalculateNuclearRad(fAtom    168     fNuclearRadius = CalculateNuclearRad(fAtomicWeight);
169     fNuclearRadius += R1;                         169     fNuclearRadius += R1;
170                                                   170 
171     if(verboseLevel > 0)                          171     if(verboseLevel > 0) 
172     {                                             172     {   
173       G4cout<<"G4NuclNuclDiffuseElastic::Initi    173       G4cout<<"G4NuclNuclDiffuseElastic::Initialise() the element: "
174       <<(*theElementTable)[jEl]->GetName()<<G4    174       <<(*theElementTable)[jEl]->GetName()<<G4endl;
175     }                                             175     }
176     fElementNumberVector.push_back(fAtomicNumb    176     fElementNumberVector.push_back(fAtomicNumber);
177     fElementNameVector.push_back((*theElementT    177     fElementNameVector.push_back((*theElementTable)[jEl]->GetName());
178                                                   178 
179     BuildAngleTable();                            179     BuildAngleTable();
180     fAngleBank.push_back(fAngleTable);            180     fAngleBank.push_back(fAngleTable);
181   }                                               181   }  
182 }                                                 182 }
183                                                   183 
184                                                   184 
185 //////////////////////////////////////////////    185 ////////////////////////////////////////////////////////////////////////////
186 //                                                186 //
187 // return differential elastic cross section d    187 // return differential elastic cross section d(sigma)/d(omega) 
188                                                   188 
189 G4double                                          189 G4double 
190 G4NuclNuclDiffuseElastic::GetDiffuseElasticXsc    190 G4NuclNuclDiffuseElastic::GetDiffuseElasticXsc( const G4ParticleDefinition* particle, 
191                                         G4doub    191                                         G4double theta, 
192                       G4double momentum,          192                       G4double momentum, 
193                                         G4doub    193                                         G4double A         )
194 {                                                 194 {
195   fParticle      = particle;                      195   fParticle      = particle;
196   fWaveVector    = momentum/hbarc;                196   fWaveVector    = momentum/hbarc;
197   fAtomicWeight  = A;                             197   fAtomicWeight  = A;
198   fAddCoulomb    = false;                         198   fAddCoulomb    = false;
199   fNuclearRadius = CalculateNuclearRad(A);        199   fNuclearRadius = CalculateNuclearRad(A);
200                                                   200 
201   G4double sigma = fNuclearRadius*fNuclearRadi    201   G4double sigma = fNuclearRadius*fNuclearRadius*GetDiffElasticProb(theta);
202                                                   202 
203   return sigma;                                   203   return sigma;
204 }                                                 204 }
205                                                   205 
206 //////////////////////////////////////////////    206 ////////////////////////////////////////////////////////////////////////////
207 //                                                207 //
208 // return invariant differential elastic cross    208 // return invariant differential elastic cross section d(sigma)/d(tMand) 
209                                                   209 
210 G4double                                          210 G4double 
211 G4NuclNuclDiffuseElastic::GetInvElasticXsc( co    211 G4NuclNuclDiffuseElastic::GetInvElasticXsc( const G4ParticleDefinition* particle, 
212                                         G4doub    212                                         G4double tMand, 
213                       G4double plab,              213                       G4double plab, 
214                                         G4doub    214                                         G4double A, G4double Z         )
215 {                                                 215 {
216   G4double m1 = particle->GetPDGMass();           216   G4double m1 = particle->GetPDGMass();
217   G4LorentzVector lv1(0.,0.,plab,std::sqrt(pla    217   G4LorentzVector lv1(0.,0.,plab,std::sqrt(plab*plab+m1*m1));
218                                                   218 
219   G4int iZ = static_cast<G4int>(Z+0.5);           219   G4int iZ = static_cast<G4int>(Z+0.5);
220   G4int iA = static_cast<G4int>(A+0.5);           220   G4int iA = static_cast<G4int>(A+0.5);
221   G4ParticleDefinition * theDef = 0;              221   G4ParticleDefinition * theDef = 0;
222                                                   222 
223   if      (iZ == 1 && iA == 1) theDef = thePro    223   if      (iZ == 1 && iA == 1) theDef = theProton;
224   else if (iZ == 1 && iA == 2) theDef = theDeu    224   else if (iZ == 1 && iA == 2) theDef = theDeuteron;
225   else if (iZ == 1 && iA == 3) theDef = G4Trit    225   else if (iZ == 1 && iA == 3) theDef = G4Triton::Triton();
226   else if (iZ == 2 && iA == 3) theDef = G4He3:    226   else if (iZ == 2 && iA == 3) theDef = G4He3::He3();
227   else if (iZ == 2 && iA == 4) theDef = theAlp    227   else if (iZ == 2 && iA == 4) theDef = theAlpha;
228   else theDef = G4ParticleTable::GetParticleTa    228   else theDef = G4ParticleTable::GetParticleTable()->GetIonTable()->GetIon(iZ,iA,0);
229                                                   229  
230   G4double tmass = theDef->GetPDGMass();          230   G4double tmass = theDef->GetPDGMass();
231                                                   231 
232   G4LorentzVector lv(0.0,0.0,0.0,tmass);          232   G4LorentzVector lv(0.0,0.0,0.0,tmass);   
233   lv += lv1;                                      233   lv += lv1;
234                                                   234 
235   G4ThreeVector bst = lv.boostVector();           235   G4ThreeVector bst = lv.boostVector();
236   lv1.boost(-bst);                                236   lv1.boost(-bst);
237                                                   237 
238   G4ThreeVector p1 = lv1.vect();                  238   G4ThreeVector p1 = lv1.vect();
239   G4double ptot    = p1.mag();                    239   G4double ptot    = p1.mag();
240   G4double ptot2 = ptot*ptot;                     240   G4double ptot2 = ptot*ptot;
241   G4double cost = 1 - 0.5*std::fabs(tMand)/pto    241   G4double cost = 1 - 0.5*std::fabs(tMand)/ptot2;
242                                                   242 
243   if( cost >= 1.0 )      cost = 1.0;              243   if( cost >= 1.0 )      cost = 1.0;  
244   else if( cost <= -1.0) cost = -1.0;             244   else if( cost <= -1.0) cost = -1.0;
245                                                   245   
246   G4double thetaCMS = std::acos(cost);            246   G4double thetaCMS = std::acos(cost);
247                                                   247 
248   G4double sigma = GetDiffuseElasticXsc( parti    248   G4double sigma = GetDiffuseElasticXsc( particle, thetaCMS, ptot, A);
249                                                   249 
250   sigma *= pi/ptot2;                              250   sigma *= pi/ptot2;
251                                                   251 
252   return sigma;                                   252   return sigma;
253 }                                                 253 }
254                                                   254 
255 //////////////////////////////////////////////    255 ////////////////////////////////////////////////////////////////////////////
256 //                                                256 //
257 // return differential elastic cross section d    257 // return differential elastic cross section d(sigma)/d(omega) with Coulomb
258 // correction                                     258 // correction
259                                                   259 
260 G4double                                          260 G4double 
261 G4NuclNuclDiffuseElastic::GetDiffuseElasticSum    261 G4NuclNuclDiffuseElastic::GetDiffuseElasticSumXsc( const G4ParticleDefinition* particle, 
262                                         G4doub    262                                         G4double theta, 
263                       G4double momentum,          263                       G4double momentum, 
264                                         G4doub    264                                         G4double A, G4double Z         )
265 {                                                 265 {
266   fParticle      = particle;                      266   fParticle      = particle;
267   fWaveVector    = momentum/hbarc;                267   fWaveVector    = momentum/hbarc;
268   fAtomicWeight  = A;                             268   fAtomicWeight  = A;
269   fAtomicNumber  = Z;                             269   fAtomicNumber  = Z;
270   fNuclearRadius = CalculateNuclearRad(A);        270   fNuclearRadius = CalculateNuclearRad(A);
271   fAddCoulomb    = false;                         271   fAddCoulomb    = false;
272                                                   272 
273   G4double z     = particle->GetPDGCharge();      273   G4double z     = particle->GetPDGCharge();
274                                                   274 
275   G4double kRt   = fWaveVector*fNuclearRadius*    275   G4double kRt   = fWaveVector*fNuclearRadius*theta;
276   G4double kRtC  = 1.9;                           276   G4double kRtC  = 1.9;
277                                                   277 
278   if( z && (kRt > kRtC) )                         278   if( z && (kRt > kRtC) )
279   {                                               279   {
280     fAddCoulomb = true;                           280     fAddCoulomb = true;
281     fBeta       = CalculateParticleBeta( parti    281     fBeta       = CalculateParticleBeta( particle, momentum);
282     fZommerfeld = CalculateZommerfeld( fBeta,     282     fZommerfeld = CalculateZommerfeld( fBeta, z, fAtomicNumber);
283     fAm         = CalculateAm( momentum, fZomm    283     fAm         = CalculateAm( momentum, fZommerfeld, fAtomicNumber);
284   }                                               284   }
285   G4double sigma = fNuclearRadius*fNuclearRadi    285   G4double sigma = fNuclearRadius*fNuclearRadius*GetDiffElasticSumProb(theta);
286                                                   286 
287   return sigma;                                   287   return sigma;
288 }                                                 288 }
289                                                   289 
290 //////////////////////////////////////////////    290 ////////////////////////////////////////////////////////////////////////////
291 //                                                291 //
292 // return invariant differential elastic cross    292 // return invariant differential elastic cross section d(sigma)/d(tMand) with Coulomb
293 // correction                                     293 // correction
294                                                   294 
295 G4double                                          295 G4double 
296 G4NuclNuclDiffuseElastic::GetInvElasticSumXsc(    296 G4NuclNuclDiffuseElastic::GetInvElasticSumXsc( const G4ParticleDefinition* particle, 
297                                         G4doub    297                                         G4double tMand, 
298                       G4double plab,              298                       G4double plab, 
299                                         G4doub    299                                         G4double A, G4double Z         )
300 {                                                 300 {
301   G4double m1 = particle->GetPDGMass();           301   G4double m1 = particle->GetPDGMass();
302                                                   302 
303   G4LorentzVector lv1(0.,0.,plab,std::sqrt(pla    303   G4LorentzVector lv1(0.,0.,plab,std::sqrt(plab*plab+m1*m1));
304                                                   304 
305   G4int iZ = static_cast<G4int>(Z+0.5);           305   G4int iZ = static_cast<G4int>(Z+0.5);
306   G4int iA = static_cast<G4int>(A+0.5);           306   G4int iA = static_cast<G4int>(A+0.5);
307                                                   307 
308   G4ParticleDefinition* theDef = 0;               308   G4ParticleDefinition* theDef = 0;
309                                                   309 
310   if      (iZ == 1 && iA == 1) theDef = thePro    310   if      (iZ == 1 && iA == 1) theDef = theProton;
311   else if (iZ == 1 && iA == 2) theDef = theDeu    311   else if (iZ == 1 && iA == 2) theDef = theDeuteron;
312   else if (iZ == 1 && iA == 3) theDef = G4Trit    312   else if (iZ == 1 && iA == 3) theDef = G4Triton::Triton();
313   else if (iZ == 2 && iA == 3) theDef = G4He3:    313   else if (iZ == 2 && iA == 3) theDef = G4He3::He3();
314   else if (iZ == 2 && iA == 4) theDef = theAlp    314   else if (iZ == 2 && iA == 4) theDef = theAlpha;
315   else theDef = G4ParticleTable::GetParticleTa    315   else theDef = G4ParticleTable::GetParticleTable()->GetIonTable()->GetIon(iZ,iA,0);
316                                                   316  
317   G4double tmass = theDef->GetPDGMass();          317   G4double tmass = theDef->GetPDGMass();
318                                                   318 
319   G4LorentzVector lv(0.0,0.0,0.0,tmass);          319   G4LorentzVector lv(0.0,0.0,0.0,tmass);   
320   lv += lv1;                                      320   lv += lv1;
321                                                   321 
322   G4ThreeVector bst = lv.boostVector();           322   G4ThreeVector bst = lv.boostVector();
323   lv1.boost(-bst);                                323   lv1.boost(-bst);
324                                                   324 
325   G4ThreeVector p1 = lv1.vect();                  325   G4ThreeVector p1 = lv1.vect();
326   G4double ptot    = p1.mag();                    326   G4double ptot    = p1.mag();
327   G4double ptot2   = ptot*ptot;                   327   G4double ptot2   = ptot*ptot;
328   G4double cost    = 1 - 0.5*std::fabs(tMand)/    328   G4double cost    = 1 - 0.5*std::fabs(tMand)/ptot2;
329                                                   329 
330   if( cost >= 1.0 )      cost = 1.0;              330   if( cost >= 1.0 )      cost = 1.0;  
331   else if( cost <= -1.0) cost = -1.0;             331   else if( cost <= -1.0) cost = -1.0;
332                                                   332   
333   G4double thetaCMS = std::acos(cost);            333   G4double thetaCMS = std::acos(cost);
334                                                   334 
335   G4double sigma = GetDiffuseElasticSumXsc( pa    335   G4double sigma = GetDiffuseElasticSumXsc( particle, thetaCMS, ptot, A, Z );
336                                                   336 
337   sigma *= pi/ptot2;                              337   sigma *= pi/ptot2;
338                                                   338 
339   return sigma;                                   339   return sigma;
340 }                                                 340 }
341                                                   341 
342 //////////////////////////////////////////////    342 ////////////////////////////////////////////////////////////////////////////
343 //                                                343 //
344 // return invariant differential elastic cross    344 // return invariant differential elastic cross section d(sigma)/d(tMand) with Coulomb
345 // correction                                     345 // correction
346                                                   346 
347 G4double                                          347 G4double 
348 G4NuclNuclDiffuseElastic::GetInvCoulombElastic    348 G4NuclNuclDiffuseElastic::GetInvCoulombElasticXsc( const G4ParticleDefinition* particle, 
349                                         G4doub    349                                         G4double tMand, 
350                       G4double plab,              350                       G4double plab, 
351                                         G4doub    351                                         G4double A, G4double Z         )
352 {                                                 352 {
353   G4double m1 = particle->GetPDGMass();           353   G4double m1 = particle->GetPDGMass();
354   G4LorentzVector lv1(0.,0.,plab,std::sqrt(pla    354   G4LorentzVector lv1(0.,0.,plab,std::sqrt(plab*plab+m1*m1));
355                                                   355 
356   G4int iZ = static_cast<G4int>(Z+0.5);           356   G4int iZ = static_cast<G4int>(Z+0.5);
357   G4int iA = static_cast<G4int>(A+0.5);           357   G4int iA = static_cast<G4int>(A+0.5);
358   G4ParticleDefinition * theDef = 0;              358   G4ParticleDefinition * theDef = 0;
359                                                   359 
360   if      (iZ == 1 && iA == 1) theDef = thePro    360   if      (iZ == 1 && iA == 1) theDef = theProton;
361   else if (iZ == 1 && iA == 2) theDef = theDeu    361   else if (iZ == 1 && iA == 2) theDef = theDeuteron;
362   else if (iZ == 1 && iA == 3) theDef = G4Trit    362   else if (iZ == 1 && iA == 3) theDef = G4Triton::Triton();
363   else if (iZ == 2 && iA == 3) theDef = G4He3:    363   else if (iZ == 2 && iA == 3) theDef = G4He3::He3();
364   else if (iZ == 2 && iA == 4) theDef = theAlp    364   else if (iZ == 2 && iA == 4) theDef = theAlpha;
365   else theDef = G4ParticleTable::GetParticleTa    365   else theDef = G4ParticleTable::GetParticleTable()->GetIonTable()->GetIon(iZ,iA,0);
366                                                   366  
367   G4double tmass = theDef->GetPDGMass();          367   G4double tmass = theDef->GetPDGMass();
368                                                   368 
369   G4LorentzVector lv(0.0,0.0,0.0,tmass);          369   G4LorentzVector lv(0.0,0.0,0.0,tmass);   
370   lv += lv1;                                      370   lv += lv1;
371                                                   371 
372   G4ThreeVector bst = lv.boostVector();           372   G4ThreeVector bst = lv.boostVector();
373   lv1.boost(-bst);                                373   lv1.boost(-bst);
374                                                   374 
375   G4ThreeVector p1 = lv1.vect();                  375   G4ThreeVector p1 = lv1.vect();
376   G4double ptot    = p1.mag();                    376   G4double ptot    = p1.mag();
377   G4double ptot2 = ptot*ptot;                     377   G4double ptot2 = ptot*ptot;
378   G4double cost = 1 - 0.5*std::fabs(tMand)/pto    378   G4double cost = 1 - 0.5*std::fabs(tMand)/ptot2;
379                                                   379 
380   if( cost >= 1.0 )      cost = 1.0;              380   if( cost >= 1.0 )      cost = 1.0;  
381   else if( cost <= -1.0) cost = -1.0;             381   else if( cost <= -1.0) cost = -1.0;
382                                                   382   
383   G4double thetaCMS = std::acos(cost);            383   G4double thetaCMS = std::acos(cost);
384                                                   384 
385   G4double sigma = GetCoulombElasticXsc( parti    385   G4double sigma = GetCoulombElasticXsc( particle, thetaCMS, ptot, Z );
386                                                   386 
387   sigma *= pi/ptot2;                              387   sigma *= pi/ptot2;
388                                                   388 
389   return sigma;                                   389   return sigma;
390 }                                                 390 }
391                                                   391 
392 //////////////////////////////////////////////    392 ////////////////////////////////////////////////////////////////////////////
393 //                                                393 //
394 // return differential elastic probability d(p    394 // return differential elastic probability d(probability)/d(omega) 
395                                                   395 
396 G4double                                          396 G4double 
397 G4NuclNuclDiffuseElastic::GetDiffElasticProb(     397 G4NuclNuclDiffuseElastic::GetDiffElasticProb( // G4ParticleDefinition* particle, 
398                                         G4doub    398                                         G4double theta 
399           //  G4double momentum,                  399           //  G4double momentum, 
400           // G4double A                           400           // G4double A         
401                                      )            401                                      )
402 {                                                 402 {
403   G4double sigma, bzero, bzero2, bonebyarg, bo    403   G4double sigma, bzero, bzero2, bonebyarg, bonebyarg2, damp, damp2;
404   G4double delta, diffuse, gamma;                 404   G4double delta, diffuse, gamma;
405   G4double e1, e2, bone, bone2;                   405   G4double e1, e2, bone, bone2;
406                                                   406 
407   // G4double wavek = momentum/hbarc;  // wave    407   // G4double wavek = momentum/hbarc;  // wave vector
408   // G4double r0    = 1.08*fermi;                 408   // G4double r0    = 1.08*fermi;
409   // G4double rad   = r0*G4Pow::GetInstance()-    409   // G4double rad   = r0*G4Pow::GetInstance()->A13(A);
410                                                   410 
411   G4double kr    = fWaveVector*fNuclearRadius;    411   G4double kr    = fWaveVector*fNuclearRadius; // wavek*rad;
412   G4double kr2   = kr*kr;                         412   G4double kr2   = kr*kr;
413   G4double krt   = kr*theta;                      413   G4double krt   = kr*theta;
414                                                   414 
415   bzero      = BesselJzero(krt);                  415   bzero      = BesselJzero(krt);
416   bzero2     = bzero*bzero;                       416   bzero2     = bzero*bzero;    
417   bone       = BesselJone(krt);                   417   bone       = BesselJone(krt);
418   bone2      = bone*bone;                         418   bone2      = bone*bone;
419   bonebyarg  = BesselOneByArg(krt);               419   bonebyarg  = BesselOneByArg(krt);
420   bonebyarg2 = bonebyarg*bonebyarg;               420   bonebyarg2 = bonebyarg*bonebyarg;  
421                                                   421 
422   // VI - Coverity complains                      422   // VI - Coverity complains
423   /*                                              423   /*
424   if (fParticle == theProton)                     424   if (fParticle == theProton)
425   {                                               425   {
426     diffuse = 0.63*fermi;                         426     diffuse = 0.63*fermi;
427     gamma   = 0.3*fermi;                          427     gamma   = 0.3*fermi;
428     delta   = 0.1*fermi*fermi;                    428     delta   = 0.1*fermi*fermi;
429     e1      = 0.3*fermi;                          429     e1      = 0.3*fermi;
430     e2      = 0.35*fermi;                         430     e2      = 0.35*fermi;
431   }                                               431   }
432   else // as proton, if were not defined          432   else // as proton, if were not defined 
433   {                                               433   {
434   */                                              434   */
435     diffuse = 0.63*fermi;                         435     diffuse = 0.63*fermi;
436     gamma   = 0.3*fermi;                          436     gamma   = 0.3*fermi;
437     delta   = 0.1*fermi*fermi;                    437     delta   = 0.1*fermi*fermi;
438     e1      = 0.3*fermi;                          438     e1      = 0.3*fermi;
439     e2      = 0.35*fermi;                         439     e2      = 0.35*fermi;
440     //}                                           440     //}
441   G4double lambda = 15.; // 15 ok                 441   G4double lambda = 15.; // 15 ok
442                                                   442 
443   //  G4double kgamma    = fWaveVector*gamma;     443   //  G4double kgamma    = fWaveVector*gamma;   // wavek*delta;
444                                                   444 
445   G4double kgamma    = lambda*(1.-G4Exp(-fWave    445   G4double kgamma    = lambda*(1.-G4Exp(-fWaveVector*gamma/lambda));   // wavek*delta;
446   G4double kgamma2   = kgamma*kgamma;             446   G4double kgamma2   = kgamma*kgamma;
447                                                   447 
448   // G4double dk2t  = delta*fWaveVector*fWaveV    448   // G4double dk2t  = delta*fWaveVector*fWaveVector*theta; // delta*wavek*wavek*theta;
449   // G4double dk2t2 = dk2t*dk2t;                  449   // G4double dk2t2 = dk2t*dk2t;
450   // G4double pikdt = pi*fWaveVector*diffuse*t    450   // G4double pikdt = pi*fWaveVector*diffuse*theta;// pi*wavek*diffuse*theta;
451                                                   451 
452   G4double pikdt    = lambda*(1.-G4Exp(-pi*fWa    452   G4double pikdt    = lambda*(1.-G4Exp(-pi*fWaveVector*diffuse*theta/lambda));   // wavek*delta;
453                                                   453 
454   damp           = DampFactor(pikdt);             454   damp           = DampFactor(pikdt);
455   damp2          = damp*damp;                     455   damp2          = damp*damp;
456                                                   456 
457   G4double mode2k2 = (e1*e1+e2*e2)*fWaveVector    457   G4double mode2k2 = (e1*e1+e2*e2)*fWaveVector*fWaveVector;  
458   G4double e2dk3t  = -2.*e2*delta*fWaveVector*    458   G4double e2dk3t  = -2.*e2*delta*fWaveVector*fWaveVector*fWaveVector*theta;
459                                                   459 
460                                                   460 
461   sigma  = kgamma2;                               461   sigma  = kgamma2;
462   // sigma  += dk2t2;                             462   // sigma  += dk2t2;
463   sigma *= bzero2;                                463   sigma *= bzero2;
464   sigma += mode2k2*bone2 + e2dk3t*bzero*bone;     464   sigma += mode2k2*bone2 + e2dk3t*bzero*bone;
465   sigma += kr2*bonebyarg2;                        465   sigma += kr2*bonebyarg2;
466   sigma *= damp2;          // *rad*rad;           466   sigma *= damp2;          // *rad*rad;
467                                                   467 
468   return sigma;                                   468   return sigma;
469 }                                                 469 }
470                                                   470 
471 //////////////////////////////////////////////    471 ////////////////////////////////////////////////////////////////////////////
472 //                                                472 //
473 // return differential elastic probability d(p    473 // return differential elastic probability d(probability)/d(omega) with 
474 // Coulomb correction                             474 // Coulomb correction
475                                                   475 
476 G4double                                          476 G4double 
477 G4NuclNuclDiffuseElastic::GetDiffElasticSumPro    477 G4NuclNuclDiffuseElastic::GetDiffElasticSumProb( // G4ParticleDefinition* particle, 
478                                         G4doub    478                                         G4double theta 
479           //  G4double momentum,                  479           //  G4double momentum, 
480           // G4double A                           480           // G4double A         
481                                      )            481                                      )
482 {                                                 482 {
483   G4double sigma, bzero, bzero2, bonebyarg, bo    483   G4double sigma, bzero, bzero2, bonebyarg, bonebyarg2, damp, damp2;
484   G4double delta, diffuse, gamma;                 484   G4double delta, diffuse, gamma;
485   G4double e1, e2, bone, bone2;                   485   G4double e1, e2, bone, bone2;
486                                                   486 
487   // G4double wavek = momentum/hbarc;  // wave    487   // G4double wavek = momentum/hbarc;  // wave vector
488   // G4double r0    = 1.08*fermi;                 488   // G4double r0    = 1.08*fermi;
489   // G4double rad   = r0*G4Pow::GetInstance()-    489   // G4double rad   = r0*G4Pow::GetInstance()->A13(A);
490                                                   490 
491   G4double kr    = fWaveVector*fNuclearRadius;    491   G4double kr    = fWaveVector*fNuclearRadius; // wavek*rad;
492   G4double kr2   = kr*kr;                         492   G4double kr2   = kr*kr;
493   G4double krt   = kr*theta;                      493   G4double krt   = kr*theta;
494                                                   494 
495   bzero      = BesselJzero(krt);                  495   bzero      = BesselJzero(krt);
496   bzero2     = bzero*bzero;                       496   bzero2     = bzero*bzero;    
497   bone       = BesselJone(krt);                   497   bone       = BesselJone(krt);
498   bone2      = bone*bone;                         498   bone2      = bone*bone;
499   bonebyarg  = BesselOneByArg(krt);               499   bonebyarg  = BesselOneByArg(krt);
500   bonebyarg2 = bonebyarg*bonebyarg;               500   bonebyarg2 = bonebyarg*bonebyarg;  
501                                                   501 
502   if (fParticle == theProton)                     502   if (fParticle == theProton)
503   {                                               503   {
504     diffuse = 0.63*fermi;                         504     diffuse = 0.63*fermi;
505     // diffuse = 0.6*fermi;                       505     // diffuse = 0.6*fermi;
506     gamma   = 0.3*fermi;                          506     gamma   = 0.3*fermi;
507     delta   = 0.1*fermi*fermi;                    507     delta   = 0.1*fermi*fermi;
508     e1      = 0.3*fermi;                          508     e1      = 0.3*fermi;
509     e2      = 0.35*fermi;                         509     e2      = 0.35*fermi;
510   }                                               510   }
511   else // as proton, if were not defined          511   else // as proton, if were not defined 
512   {                                               512   {
513     diffuse = 0.63*fermi;                         513     diffuse = 0.63*fermi;
514     gamma   = 0.3*fermi;                          514     gamma   = 0.3*fermi;
515     delta   = 0.1*fermi*fermi;                    515     delta   = 0.1*fermi*fermi;
516     e1      = 0.3*fermi;                          516     e1      = 0.3*fermi;
517     e2      = 0.35*fermi;                         517     e2      = 0.35*fermi;
518   }                                               518   }
519   G4double lambda = 15.; // 15 ok                 519   G4double lambda = 15.; // 15 ok
520   // G4double kgamma    = fWaveVector*gamma;      520   // G4double kgamma    = fWaveVector*gamma;   // wavek*delta;
521   G4double kgamma    = lambda*(1.-G4Exp(-fWave    521   G4double kgamma    = lambda*(1.-G4Exp(-fWaveVector*gamma/lambda));   // wavek*delta;
522                                                   522 
523   // G4cout<<"kgamma = "<<kgamma<<G4endl;         523   // G4cout<<"kgamma = "<<kgamma<<G4endl;
524                                                   524 
525   if(fAddCoulomb)  // add Coulomb correction      525   if(fAddCoulomb)  // add Coulomb correction
526   {                                               526   {
527     G4double sinHalfTheta  = std::sin(0.5*thet    527     G4double sinHalfTheta  = std::sin(0.5*theta);
528     G4double sinHalfTheta2 = sinHalfTheta*sinH    528     G4double sinHalfTheta2 = sinHalfTheta*sinHalfTheta;
529                                                   529 
530     kgamma += 0.5*fZommerfeld/kr/(sinHalfTheta    530     kgamma += 0.5*fZommerfeld/kr/(sinHalfTheta2+fAm); // correction at J0()
531   // kgamma += 0.65*fZommerfeld/kr/(sinHalfThe    531   // kgamma += 0.65*fZommerfeld/kr/(sinHalfTheta2+fAm); // correction at J0()
532   }                                               532   }
533                                                   533 
534   G4double kgamma2   = kgamma*kgamma;             534   G4double kgamma2   = kgamma*kgamma;
535                                                   535 
536   // G4double dk2t  = delta*fWaveVector*fWaveV    536   // G4double dk2t  = delta*fWaveVector*fWaveVector*theta; // delta*wavek*wavek*theta;
537   //   G4cout<<"dk2t = "<<dk2t<<G4endl;           537   //   G4cout<<"dk2t = "<<dk2t<<G4endl;
538   // G4double dk2t2 = dk2t*dk2t;                  538   // G4double dk2t2 = dk2t*dk2t;
539   // G4double pikdt = pi*fWaveVector*diffuse*t    539   // G4double pikdt = pi*fWaveVector*diffuse*theta;// pi*wavek*diffuse*theta;
540                                                   540 
541   G4double pikdt    = lambda*(1.-G4Exp(-pi*fWa    541   G4double pikdt    = lambda*(1.-G4Exp(-pi*fWaveVector*diffuse*theta/lambda));   // wavek*delta;
542                                                   542 
543   // G4cout<<"pikdt = "<<pikdt<<G4endl;           543   // G4cout<<"pikdt = "<<pikdt<<G4endl;
544                                                   544 
545   damp           = DampFactor(pikdt);             545   damp           = DampFactor(pikdt);
546   damp2          = damp*damp;                     546   damp2          = damp*damp;
547                                                   547 
548   G4double mode2k2 = (e1*e1+e2*e2)*fWaveVector    548   G4double mode2k2 = (e1*e1+e2*e2)*fWaveVector*fWaveVector;  
549   G4double e2dk3t  = -2.*e2*delta*fWaveVector*    549   G4double e2dk3t  = -2.*e2*delta*fWaveVector*fWaveVector*fWaveVector*theta;
550                                                   550 
551   sigma  = kgamma2;                               551   sigma  = kgamma2;
552   // sigma += dk2t2;                              552   // sigma += dk2t2;
553   sigma *= bzero2;                                553   sigma *= bzero2;
554   sigma += mode2k2*bone2;                         554   sigma += mode2k2*bone2; 
555   sigma += e2dk3t*bzero*bone;                     555   sigma += e2dk3t*bzero*bone;
556                                                   556 
557   // sigma += kr2*(1 + 8.*fZommerfeld*fZommerf    557   // sigma += kr2*(1 + 8.*fZommerfeld*fZommerfeld/kr2)*bonebyarg2;  // correction at J1()/()
558   sigma += kr2*bonebyarg2;  // correction at J    558   sigma += kr2*bonebyarg2;  // correction at J1()/()
559                                                   559 
560   sigma *= damp2;          // *rad*rad;           560   sigma *= damp2;          // *rad*rad;
561                                                   561 
562   return sigma;                                   562   return sigma;
563 }                                                 563 }
564                                                   564 
565                                                   565 
566 //////////////////////////////////////////////    566 ////////////////////////////////////////////////////////////////////////////
567 //                                                567 //
568 // return differential elastic probability d(p    568 // return differential elastic probability d(probability)/d(t) with 
569 // Coulomb correction                             569 // Coulomb correction
570                                                   570 
571 G4double                                          571 G4double 
572 G4NuclNuclDiffuseElastic::GetDiffElasticSumPro    572 G4NuclNuclDiffuseElastic::GetDiffElasticSumProbA( G4double alpha )
573 {                                                 573 {
574   G4double theta;                                 574   G4double theta; 
575                                                   575 
576   theta = std::sqrt(alpha);                       576   theta = std::sqrt(alpha);
577                                                   577 
578   // theta = std::acos( 1 - alpha/2. );           578   // theta = std::acos( 1 - alpha/2. );
579                                                   579 
580   G4double sigma, bzero, bzero2, bonebyarg, bo    580   G4double sigma, bzero, bzero2, bonebyarg, bonebyarg2, damp, damp2;
581   G4double delta, diffuse, gamma;                 581   G4double delta, diffuse, gamma;
582   G4double e1, e2, bone, bone2;                   582   G4double e1, e2, bone, bone2;
583                                                   583 
584   // G4double wavek = momentum/hbarc;  // wave    584   // G4double wavek = momentum/hbarc;  // wave vector
585   // G4double r0    = 1.08*fermi;                 585   // G4double r0    = 1.08*fermi;
586   // G4double rad   = r0*G4Pow::GetInstance()-    586   // G4double rad   = r0*G4Pow::GetInstance()->A13(A);
587                                                   587 
588   G4double kr    = fWaveVector*fNuclearRadius;    588   G4double kr    = fWaveVector*fNuclearRadius; // wavek*rad;
589   G4double kr2   = kr*kr;                         589   G4double kr2   = kr*kr;
590   G4double krt   = kr*theta;                      590   G4double krt   = kr*theta;
591                                                   591 
592   bzero      = BesselJzero(krt);                  592   bzero      = BesselJzero(krt);
593   bzero2     = bzero*bzero;                       593   bzero2     = bzero*bzero;    
594   bone       = BesselJone(krt);                   594   bone       = BesselJone(krt);
595   bone2      = bone*bone;                         595   bone2      = bone*bone;
596   bonebyarg  = BesselOneByArg(krt);               596   bonebyarg  = BesselOneByArg(krt);
597   bonebyarg2 = bonebyarg*bonebyarg;               597   bonebyarg2 = bonebyarg*bonebyarg;  
598                                                   598 
599   if (fParticle == theProton)                     599   if (fParticle == theProton)
600   {                                               600   {
601     diffuse = 0.63*fermi;                         601     diffuse = 0.63*fermi;
602     // diffuse = 0.6*fermi;                       602     // diffuse = 0.6*fermi;
603     gamma   = 0.3*fermi;                          603     gamma   = 0.3*fermi;
604     delta   = 0.1*fermi*fermi;                    604     delta   = 0.1*fermi*fermi;
605     e1      = 0.3*fermi;                          605     e1      = 0.3*fermi;
606     e2      = 0.35*fermi;                         606     e2      = 0.35*fermi;
607   }                                               607   }
608   else // as proton, if were not defined          608   else // as proton, if were not defined 
609   {                                               609   {
610     diffuse = 0.63*fermi;                         610     diffuse = 0.63*fermi;
611     gamma   = 0.3*fermi;                          611     gamma   = 0.3*fermi;
612     delta   = 0.1*fermi*fermi;                    612     delta   = 0.1*fermi*fermi;
613     e1      = 0.3*fermi;                          613     e1      = 0.3*fermi;
614     e2      = 0.35*fermi;                         614     e2      = 0.35*fermi;
615   }                                               615   }
616   G4double lambda = 15.; // 15 ok                 616   G4double lambda = 15.; // 15 ok
617   // G4double kgamma    = fWaveVector*gamma;      617   // G4double kgamma    = fWaveVector*gamma;   // wavek*delta;
618   G4double kgamma    = lambda*(1.-G4Exp(-fWave    618   G4double kgamma    = lambda*(1.-G4Exp(-fWaveVector*gamma/lambda));   // wavek*delta;
619                                                   619 
620   // G4cout<<"kgamma = "<<kgamma<<G4endl;         620   // G4cout<<"kgamma = "<<kgamma<<G4endl;
621                                                   621 
622   if(fAddCoulomb)  // add Coulomb correction      622   if(fAddCoulomb)  // add Coulomb correction
623   {                                               623   {
624     G4double sinHalfTheta  = theta*0.5; // std    624     G4double sinHalfTheta  = theta*0.5; // std::sin(0.5*theta);
625     G4double sinHalfTheta2 = sinHalfTheta*sinH    625     G4double sinHalfTheta2 = sinHalfTheta*sinHalfTheta;
626                                                   626 
627     kgamma += 0.5*fZommerfeld/kr/(sinHalfTheta    627     kgamma += 0.5*fZommerfeld/kr/(sinHalfTheta2+fAm); // correction at J0()
628   // kgamma += 0.65*fZommerfeld/kr/(sinHalfThe    628   // kgamma += 0.65*fZommerfeld/kr/(sinHalfTheta2+fAm); // correction at J0()
629   }                                               629   }
630                                                   630 
631   G4double kgamma2   = kgamma*kgamma;             631   G4double kgamma2   = kgamma*kgamma;
632                                                   632 
633   // G4double dk2t  = delta*fWaveVector*fWaveV    633   // G4double dk2t  = delta*fWaveVector*fWaveVector*theta; // delta*wavek*wavek*theta;
634   //   G4cout<<"dk2t = "<<dk2t<<G4endl;           634   //   G4cout<<"dk2t = "<<dk2t<<G4endl;
635   // G4double dk2t2 = dk2t*dk2t;                  635   // G4double dk2t2 = dk2t*dk2t;
636   // G4double pikdt = pi*fWaveVector*diffuse*t    636   // G4double pikdt = pi*fWaveVector*diffuse*theta;// pi*wavek*diffuse*theta;
637                                                   637 
638   G4double pikdt    = lambda*(1.-G4Exp(-pi*fWa    638   G4double pikdt    = lambda*(1.-G4Exp(-pi*fWaveVector*diffuse*theta/lambda));   // wavek*delta;
639                                                   639 
640   // G4cout<<"pikdt = "<<pikdt<<G4endl;           640   // G4cout<<"pikdt = "<<pikdt<<G4endl;
641                                                   641 
642   damp           = DampFactor(pikdt);             642   damp           = DampFactor(pikdt);
643   damp2          = damp*damp;                     643   damp2          = damp*damp;
644                                                   644 
645   G4double mode2k2 = (e1*e1+e2*e2)*fWaveVector    645   G4double mode2k2 = (e1*e1+e2*e2)*fWaveVector*fWaveVector;  
646   G4double e2dk3t  = -2.*e2*delta*fWaveVector*    646   G4double e2dk3t  = -2.*e2*delta*fWaveVector*fWaveVector*fWaveVector*theta;
647                                                   647 
648   sigma  = kgamma2;                               648   sigma  = kgamma2;
649   // sigma += dk2t2;                              649   // sigma += dk2t2;
650   sigma *= bzero2;                                650   sigma *= bzero2;
651   sigma += mode2k2*bone2;                         651   sigma += mode2k2*bone2; 
652   sigma += e2dk3t*bzero*bone;                     652   sigma += e2dk3t*bzero*bone;
653                                                   653 
654   // sigma += kr2*(1 + 8.*fZommerfeld*fZommerf    654   // sigma += kr2*(1 + 8.*fZommerfeld*fZommerfeld/kr2)*bonebyarg2;  // correction at J1()/()
655   sigma += kr2*bonebyarg2;  // correction at J    655   sigma += kr2*bonebyarg2;  // correction at J1()/()
656                                                   656 
657   sigma *= damp2;          // *rad*rad;           657   sigma *= damp2;          // *rad*rad;
658                                                   658 
659   return sigma;                                   659   return sigma;
660 }                                                 660 }
661                                                   661 
662                                                   662 
663 //////////////////////////////////////////////    663 ////////////////////////////////////////////////////////////////////////////
664 //                                                664 //
665 // return differential elastic probability 2*p    665 // return differential elastic probability 2*pi*sin(theta)*d(probability)/d(omega) 
666                                                   666 
667 G4double                                          667 G4double 
668 G4NuclNuclDiffuseElastic::GetIntegrandFunction    668 G4NuclNuclDiffuseElastic::GetIntegrandFunction( G4double alpha )
669 {                                                 669 {
670   G4double result;                                670   G4double result;
671                                                   671 
672   result  = GetDiffElasticSumProbA(alpha);        672   result  = GetDiffElasticSumProbA(alpha);
673                                                   673 
674   // result *= 2*pi*std::sin(theta);              674   // result *= 2*pi*std::sin(theta);
675                                                   675 
676   return result;                                  676   return result;
677 }                                                 677 }
678                                                   678 
679 //////////////////////////////////////////////    679 ////////////////////////////////////////////////////////////////////////////
680 //                                                680 //
681 // return integral elastic cross section d(sig    681 // return integral elastic cross section d(sigma)/d(omega) integrated 0 - theta 
682                                                   682 
683 G4double                                          683 G4double 
684 G4NuclNuclDiffuseElastic::IntegralElasticProb(    684 G4NuclNuclDiffuseElastic::IntegralElasticProb(  const G4ParticleDefinition* particle, 
685                                         G4doub    685                                         G4double theta, 
686                       G4double momentum,          686                       G4double momentum, 
687                                         G4doub    687                                         G4double A         )
688 {                                                 688 {
689   G4double result;                                689   G4double result;
690   fParticle      = particle;                      690   fParticle      = particle;
691   fWaveVector    = momentum/hbarc;                691   fWaveVector    = momentum/hbarc;
692   fAtomicWeight  = A;                             692   fAtomicWeight  = A;
693                                                   693 
694   fNuclearRadius = CalculateNuclearRad(A);        694   fNuclearRadius = CalculateNuclearRad(A);
695                                                   695 
696                                                   696 
697   G4Integrator<G4NuclNuclDiffuseElastic,G4doub    697   G4Integrator<G4NuclNuclDiffuseElastic,G4double(G4NuclNuclDiffuseElastic::*)(G4double)> integral;
698                                                   698 
699   // result = integral.Legendre10(this,&G4Nucl    699   // result = integral.Legendre10(this,&G4NuclNuclDiffuseElastic::GetIntegrandFunction, 0., theta ); 
700   result = integral.Legendre96(this,&G4NuclNuc    700   result = integral.Legendre96(this,&G4NuclNuclDiffuseElastic::GetIntegrandFunction, 0., theta ); 
701                                                   701 
702   return result;                                  702   return result;
703 }                                                 703 }
704                                                   704 
705 //////////////////////////////////////////////    705 ////////////////////////////////////////////////////////////////////////////
706 //                                                706 //
707 // Return inv momentum transfer -t > 0            707 // Return inv momentum transfer -t > 0
708                                                   708 
709 G4double G4NuclNuclDiffuseElastic::SampleT( co    709 G4double G4NuclNuclDiffuseElastic::SampleT( const G4ParticleDefinition* aParticle, 
710               G4double p, G4double A)             710               G4double p, G4double A)
711 {                                                 711 {
712   G4double theta = SampleThetaCMS( aParticle,     712   G4double theta = SampleThetaCMS( aParticle,  p, A); // sample theta in cms
713   G4double t     = 2*p*p*( 1 - std::cos(theta)    713   G4double t     = 2*p*p*( 1 - std::cos(theta) ); // -t !!!
714   return t;                                       714   return t;
715 }                                                 715 }
716                                                   716 
717 //////////////////////////////////////////////    717 ////////////////////////////////////////////////////////////////////////////
718 //                                                718 //
719 // Return scattering angle sampled in cms         719 // Return scattering angle sampled in cms
720                                                   720 
721                                                   721 
722 G4double                                          722 G4double 
723 G4NuclNuclDiffuseElastic::SampleThetaCMS(const    723 G4NuclNuclDiffuseElastic::SampleThetaCMS(const G4ParticleDefinition* particle, 
724                                        G4doubl    724                                        G4double momentum, G4double A)
725 {                                                 725 {
726   G4int i, iMax = 100;                            726   G4int i, iMax = 100;  
727   G4double norm, theta1, theta2, thetaMax;     << 727   G4double norm, result, theta1, theta2, thetaMax, sum = 0.;
728   G4double result = 0., sum = 0.;              << 
729                                                   728 
730   fParticle      = particle;                      729   fParticle      = particle;
731   fWaveVector    = momentum/hbarc;                730   fWaveVector    = momentum/hbarc;
732   fAtomicWeight  = A;                             731   fAtomicWeight  = A;
733                                                   732 
734   fNuclearRadius = CalculateNuclearRad(A);        733   fNuclearRadius = CalculateNuclearRad(A);
735                                                   734   
736   thetaMax = 10.174/fWaveVector/fNuclearRadius    735   thetaMax = 10.174/fWaveVector/fNuclearRadius;
737                                                   736 
738   if (thetaMax > pi) thetaMax = pi;               737   if (thetaMax > pi) thetaMax = pi;
739                                                   738 
740   G4Integrator<G4NuclNuclDiffuseElastic,G4doub    739   G4Integrator<G4NuclNuclDiffuseElastic,G4double(G4NuclNuclDiffuseElastic::*)(G4double)> integral;
741                                                   740 
742   // result = integral.Legendre10(this,&G4Nucl    741   // result = integral.Legendre10(this,&G4NuclNuclDiffuseElastic::GetIntegrandFunction, 0., theta ); 
743   norm = integral.Legendre96(this,&G4NuclNuclD    742   norm = integral.Legendre96(this,&G4NuclNuclDiffuseElastic::GetIntegrandFunction, 0., thetaMax );
744                                                   743 
745   norm *= G4UniformRand();                        744   norm *= G4UniformRand();
746                                                   745 
747   for(i = 1; i <= iMax; i++)                      746   for(i = 1; i <= iMax; i++)
748   {                                               747   {
749     theta1 = (i-1)*thetaMax/iMax;                 748     theta1 = (i-1)*thetaMax/iMax; 
750     theta2 = i*thetaMax/iMax;                     749     theta2 = i*thetaMax/iMax;
751     sum   += integral.Legendre10(this,&G4NuclN    750     sum   += integral.Legendre10(this,&G4NuclNuclDiffuseElastic::GetIntegrandFunction, theta1, theta2);
752                                                   751 
753     if ( sum >= norm )                            752     if ( sum >= norm ) 
754     {                                             753     {
755       result = 0.5*(theta1 + theta2);             754       result = 0.5*(theta1 + theta2);
756       break;                                      755       break;
757     }                                             756     }
758   }                                               757   }
759   if (i > iMax ) result = 0.5*(theta1 + theta2    758   if (i > iMax ) result = 0.5*(theta1 + theta2);
760                                                   759 
761   G4double sigma = pi*thetaMax/iMax;              760   G4double sigma = pi*thetaMax/iMax;
762                                                   761 
763   result += G4RandGauss::shoot(0.,sigma);         762   result += G4RandGauss::shoot(0.,sigma);
764                                                   763 
765   if(result < 0.) result = 0.;                    764   if(result < 0.) result = 0.;
766   if(result > thetaMax) result = thetaMax;        765   if(result > thetaMax) result = thetaMax;
767                                                   766 
768   return result;                                  767   return result;
769 }                                                 768 }
770                                                   769 
771 //////////////////////////////////////////////    770 /////////////////////////////////////////////////////////////////////////////
772 /////////////////////  Table preparation and r    771 /////////////////////  Table preparation and reading ////////////////////////
773                                                   772 
774 //////////////////////////////////////////////    773 ////////////////////////////////////////////////////////////////////////////
775 //                                                774 //
776 // Interface function. Return inv momentum tra    775 // Interface function. Return inv momentum transfer -t > 0 from initialisation table
777                                                   776 
778 G4double G4NuclNuclDiffuseElastic::SampleInvar    777 G4double G4NuclNuclDiffuseElastic::SampleInvariantT( const G4ParticleDefinition* aParticle, G4double p, 
779                                                   778                                                G4int Z, G4int A)
780 {                                                 779 {
781   fParticle = aParticle;                          780   fParticle = aParticle;
782   fAtomicNumber = G4double(Z);                    781   fAtomicNumber = G4double(Z);
783   fAtomicWeight = G4double(A);                    782   fAtomicWeight = G4double(A);
784                                                   783 
785   G4double t(0.), m1 = fParticle->GetPDGMass()    784   G4double t(0.), m1 = fParticle->GetPDGMass();
786   G4double totElab = std::sqrt(m1*m1+p*p);        785   G4double totElab = std::sqrt(m1*m1+p*p);
787   G4double mass2 = G4NucleiProperties::GetNucl    786   G4double mass2 = G4NucleiProperties::GetNuclearMass(A, Z);
788   G4LorentzVector lv1(p,0.0,0.0,totElab);         787   G4LorentzVector lv1(p,0.0,0.0,totElab);
789   G4LorentzVector  lv(0.0,0.0,0.0,mass2);         788   G4LorentzVector  lv(0.0,0.0,0.0,mass2);   
790   lv += lv1;                                      789   lv += lv1;
791                                                   790 
792   G4ThreeVector bst = lv.boostVector();           791   G4ThreeVector bst = lv.boostVector();
793   lv1.boost(-bst);                                792   lv1.boost(-bst);
794                                                   793 
795   G4ThreeVector p1 = lv1.vect();                  794   G4ThreeVector p1 = lv1.vect();
796   G4double momentumCMS = p1.mag();                795   G4double momentumCMS = p1.mag();
797                                                   796 
798   // t = SampleTableT( aParticle,  momentumCMS    797   // t = SampleTableT( aParticle,  momentumCMS, G4double(Z), G4double(A) ); // sample theta2 in cms
799                                                   798 
800   t = SampleCoulombMuCMS( aParticle,  momentum    799   t = SampleCoulombMuCMS( aParticle,  momentumCMS); // sample theta2 in cms
801                                                   800 
802                                                   801 
803   return t;                                       802   return t;
804 }                                                 803 }
805                                                   804 
806 //////////////////////////////////////////////    805 ////////////////////////////////////////////////////////////////////////////
807 //                                                806 //
808 // Return inv momentum transfer -t > 0 as Coul    807 // Return inv momentum transfer -t > 0 as Coulomb scattering <= thetaC
809                                                   808 
810 G4double G4NuclNuclDiffuseElastic::SampleCoulo    809 G4double G4NuclNuclDiffuseElastic::SampleCoulombMuCMS( const G4ParticleDefinition* aParticle, G4double p)
811 {                                                 810 {
812   G4double t(0.), rand(0.), mu(0.);               811   G4double t(0.), rand(0.), mu(0.);
813                                                   812 
814   G4double A1 = G4double( aParticle->GetBaryon    813   G4double A1 = G4double( aParticle->GetBaryonNumber() );
815   G4double R1 = CalculateNuclearRad(A1);          814   G4double R1 = CalculateNuclearRad(A1);
816                                                   815 
817   fNuclearRadius  = CalculateNuclearRad(fAtomi    816   fNuclearRadius  = CalculateNuclearRad(fAtomicWeight);
818   fNuclearRadius += R1;                           817   fNuclearRadius += R1;
819                                                   818 
820   InitDynParameters(fParticle, p);                819   InitDynParameters(fParticle, p);
821                                                   820 
822   fCoulombMuC = fHalfRutThetaTg2/(1.+fHalfRutT    821   fCoulombMuC = fHalfRutThetaTg2/(1.+fHalfRutThetaTg2);
823                                                   822 
824   rand = G4UniformRand();                         823   rand = G4UniformRand();
825                                                   824 
826   // sample (1-cosTheta) in 0 < Theta < ThetaC    825   // sample (1-cosTheta) in 0 < Theta < ThetaC as Coulomb scattering
827                                                   826 
828   mu  = fCoulombMuC*rand*fAm;                     827   mu  = fCoulombMuC*rand*fAm;
829   mu /= fAm + fCoulombMuC*( 1. - rand );          828   mu /= fAm + fCoulombMuC*( 1. - rand );
830                                                   829 
831   t = 4.*p*p*mu;                                  830   t = 4.*p*p*mu;
832                                                   831 
833   return t;                                       832   return t;
834 }                                                 833 }
835                                                   834 
836                                                   835 
837 //////////////////////////////////////////////    836 ////////////////////////////////////////////////////////////////////////////
838 //                                                837 //
839 // Return inv momentum transfer -t > 0 from in    838 // Return inv momentum transfer -t > 0 from initialisation table
840                                                   839 
841 G4double G4NuclNuclDiffuseElastic::SampleTable    840 G4double G4NuclNuclDiffuseElastic::SampleTableT( const G4ParticleDefinition* aParticle, G4double p, 
842                                                   841                                                G4double Z, G4double A)
843 {                                                 842 {
844   G4double alpha = SampleTableThetaCMS( aParti    843   G4double alpha = SampleTableThetaCMS( aParticle,  p, Z, A); // sample theta2 in cms
845   // G4double t     = 2*p*p*( 1 - std::cos(std    844   // G4double t     = 2*p*p*( 1 - std::cos(std::sqrt(alpha)) );             // -t !!!
846   G4double t     = p*p*alpha;             // -    845   G4double t     = p*p*alpha;             // -t !!!
847   return t;                                       846   return t;
848 }                                                 847 }
849                                                   848 
850 //////////////////////////////////////////////    849 ////////////////////////////////////////////////////////////////////////////
851 //                                                850 //
852 // Return scattering angle2 sampled in cms acc    851 // Return scattering angle2 sampled in cms according to precalculated table.
853                                                   852 
854                                                   853 
855 G4double                                          854 G4double 
856 G4NuclNuclDiffuseElastic::SampleTableThetaCMS(    855 G4NuclNuclDiffuseElastic::SampleTableThetaCMS(const G4ParticleDefinition* particle, 
857                                        G4doubl    856                                        G4double momentum, G4double Z, G4double A)
858 {                                                 857 {
859   std::size_t iElement;                        << 858   size_t iElement;
860   G4int iMomentum, iAngle;                        859   G4int iMomentum, iAngle;  
861   G4double randAngle, position, theta1, theta2    860   G4double randAngle, position, theta1, theta2, E1, E2, W1, W2, W;  
862   G4double m1 = particle->GetPDGMass();           861   G4double m1 = particle->GetPDGMass();
863                                                   862 
864   for(iElement = 0; iElement < fElementNumberV    863   for(iElement = 0; iElement < fElementNumberVector.size(); iElement++)
865   {                                               864   {
866     if( std::fabs(Z - fElementNumberVector[iEl    865     if( std::fabs(Z - fElementNumberVector[iElement]) < 0.5) break;
867   }                                               866   }
868   if ( iElement == fElementNumberVector.size()    867   if ( iElement == fElementNumberVector.size() ) 
869   {                                               868   {
870     InitialiseOnFly(Z,A); // table preparation    869     InitialiseOnFly(Z,A); // table preparation, if needed
871                                                   870 
872     // iElement--;                                871     // iElement--;
873                                                   872 
874     // G4cout << "G4NuclNuclDiffuseElastic: El    873     // G4cout << "G4NuclNuclDiffuseElastic: Element with atomic number " << Z
875     // << " is not found, return zero angle" <    874     // << " is not found, return zero angle" << G4endl;
876     // return 0.; // no table for this element    875     // return 0.; // no table for this element
877   }                                               876   }
878   // G4cout<<"iElement = "<<iElement<<G4endl;     877   // G4cout<<"iElement = "<<iElement<<G4endl;
879                                                   878 
880   fAngleTable = fAngleBank[iElement];             879   fAngleTable = fAngleBank[iElement];
881                                                   880 
882   G4double kinE = std::sqrt(momentum*momentum     881   G4double kinE = std::sqrt(momentum*momentum + m1*m1) - m1;
883                                                   882 
884   for( iMomentum = 0; iMomentum < fEnergyBin;     883   for( iMomentum = 0; iMomentum < fEnergyBin; iMomentum++)
885   {                                               884   {
886     // G4cout<<iMomentum<<", kinE = "<<kinE/Me    885     // G4cout<<iMomentum<<", kinE = "<<kinE/MeV<<", vectorE = "<<fEnergyVector->GetLowEdgeEnergy(iMomentum)/MeV<<G4endl;
887                                                   886     
888     if( kinE < fEnergyVector->GetLowEdgeEnergy    887     if( kinE < fEnergyVector->GetLowEdgeEnergy(iMomentum) ) break;
889   }                                               888   }
890   // G4cout<<"iMomentum = "<<iMomentum<<", fEn    889   // G4cout<<"iMomentum = "<<iMomentum<<", fEnergyBin -1 = "<<fEnergyBin -1<<G4endl;
891                                                   890 
892                                                   891 
893   if ( iMomentum >= fEnergyBin ) iMomentum = f    892   if ( iMomentum >= fEnergyBin ) iMomentum = fEnergyBin-1;   // kinE is more then theMaxEnergy
894   if ( iMomentum < 0 )           iMomentum = 0    893   if ( iMomentum < 0 )           iMomentum = 0; // against negative index, kinE < theMinEnergy
895                                                   894 
896                                                   895 
897   if (iMomentum == fEnergyBin -1 || iMomentum     896   if (iMomentum == fEnergyBin -1 || iMomentum == 0 )   // the table edges
898   {                                               897   {
899     position = (*(*fAngleTable)(iMomentum))(fA    898     position = (*(*fAngleTable)(iMomentum))(fAngleBin-2)*G4UniformRand();
900                                                   899 
901     // G4cout<<"position = "<<position<<G4endl    900     // G4cout<<"position = "<<position<<G4endl;
902                                                   901 
903     for(iAngle = 0; iAngle < fAngleBin-1; iAng    902     for(iAngle = 0; iAngle < fAngleBin-1; iAngle++)
904     {                                             903     {
905       if( position < (*(*fAngleTable)(iMomentu    904       if( position < (*(*fAngleTable)(iMomentum))(iAngle) ) break;
906     }                                             905     }
907     if (iAngle >= fAngleBin-1) iAngle = fAngle    906     if (iAngle >= fAngleBin-1) iAngle = fAngleBin-2;
908                                                   907 
909     // G4cout<<"iAngle = "<<iAngle<<G4endl;       908     // G4cout<<"iAngle = "<<iAngle<<G4endl;
910                                                   909 
911     randAngle = GetScatteringAngle(iMomentum,     910     randAngle = GetScatteringAngle(iMomentum, iAngle, position);
912                                                   911 
913     // G4cout<<"randAngle = "<<randAngle<<G4en    912     // G4cout<<"randAngle = "<<randAngle<<G4endl;
914   }                                               913   }
915   else  // kinE inside between energy table ed    914   else  // kinE inside between energy table edges
916   {                                               915   {
917     // position = (*(*fAngleTable)(iMomentum))    916     // position = (*(*fAngleTable)(iMomentum))(fAngleBin-2)*G4UniformRand();
918     position = (*(*fAngleTable)(iMomentum))(0)    917     position = (*(*fAngleTable)(iMomentum))(0)*G4UniformRand();
919                                                   918 
920     // G4cout<<"position = "<<position<<G4endl    919     // G4cout<<"position = "<<position<<G4endl;
921                                                   920 
922     for(iAngle = 0; iAngle < fAngleBin-1; iAng    921     for(iAngle = 0; iAngle < fAngleBin-1; iAngle++)
923     {                                             922     {
924       // if( position < (*(*fAngleTable)(iMome    923       // if( position < (*(*fAngleTable)(iMomentum))(iAngle) ) break;
925       if( position > (*(*fAngleTable)(iMomentu    924       if( position > (*(*fAngleTable)(iMomentum))(iAngle) ) break;
926     }                                             925     }
927     if (iAngle >= fAngleBin-1) iAngle = fAngle    926     if (iAngle >= fAngleBin-1) iAngle = fAngleBin-2;
928                                                   927 
929     // G4cout<<"iAngle = "<<iAngle<<G4endl;       928     // G4cout<<"iAngle = "<<iAngle<<G4endl;
930                                                   929 
931     theta2  = GetScatteringAngle(iMomentum, iA    930     theta2  = GetScatteringAngle(iMomentum, iAngle, position);
932                                                   931 
933     // G4cout<<"theta2 = "<<theta2<<G4endl;       932     // G4cout<<"theta2 = "<<theta2<<G4endl;
934                                                   933 
935     E2 = fEnergyVector->GetLowEdgeEnergy(iMome    934     E2 = fEnergyVector->GetLowEdgeEnergy(iMomentum);
936                                                   935 
937     // G4cout<<"E2 = "<<E2<<G4endl;               936     // G4cout<<"E2 = "<<E2<<G4endl;
938                                                   937     
939     iMomentum--;                                  938     iMomentum--;
940                                                   939     
941     // position = (*(*fAngleTable)(iMomentum))    940     // position = (*(*fAngleTable)(iMomentum))(fAngleBin-2)*G4UniformRand();
942                                                   941 
943     // G4cout<<"position = "<<position<<G4endl    942     // G4cout<<"position = "<<position<<G4endl;
944                                                   943 
945     for(iAngle = 0; iAngle < fAngleBin-1; iAng    944     for(iAngle = 0; iAngle < fAngleBin-1; iAngle++)
946     {                                             945     {
947       // if( position < (*(*fAngleTable)(iMome    946       // if( position < (*(*fAngleTable)(iMomentum))(iAngle) ) break;
948       if( position > (*(*fAngleTable)(iMomentu    947       if( position > (*(*fAngleTable)(iMomentum))(iAngle) ) break;
949     }                                             948     }
950     if (iAngle >= fAngleBin-1) iAngle = fAngle    949     if (iAngle >= fAngleBin-1) iAngle = fAngleBin-2;
951                                                   950     
952     theta1  = GetScatteringAngle(iMomentum, iA    951     theta1  = GetScatteringAngle(iMomentum, iAngle, position);
953                                                   952 
954     // G4cout<<"theta1 = "<<theta1<<G4endl;       953     // G4cout<<"theta1 = "<<theta1<<G4endl;
955                                                   954 
956     E1 = fEnergyVector->GetLowEdgeEnergy(iMome    955     E1 = fEnergyVector->GetLowEdgeEnergy(iMomentum);
957                                                   956 
958     // G4cout<<"E1 = "<<E1<<G4endl;               957     // G4cout<<"E1 = "<<E1<<G4endl;
959                                                   958 
960     W  = 1.0/(E2 - E1);                           959     W  = 1.0/(E2 - E1);
961     W1 = (E2 - kinE)*W;                           960     W1 = (E2 - kinE)*W;
962     W2 = (kinE - E1)*W;                           961     W2 = (kinE - E1)*W;
963                                                   962 
964     randAngle = W1*theta1 + W2*theta2;            963     randAngle = W1*theta1 + W2*theta2;
965                                                   964     
966     // randAngle = theta2;                        965     // randAngle = theta2;
967   }                                               966   }
968   // G4double angle = randAngle;                  967   // G4double angle = randAngle;
969   // if (randAngle > 0.) randAngle /= 2*pi*std    968   // if (randAngle > 0.) randAngle /= 2*pi*std::sin(angle);
970   // G4cout<<"randAngle = "<<randAngle/degree<    969   // G4cout<<"randAngle = "<<randAngle/degree<<G4endl;
971                                                   970 
972   return randAngle;                               971   return randAngle;
973 }                                                 972 }
974                                                   973 
975 //////////////////////////////////////////////    974 //////////////////////////////////////////////////////////////////////////////
976 //                                                975 //
977 // Initialisation for given particle on fly us    976 // Initialisation for given particle on fly using new element number
978                                                   977 
979 void G4NuclNuclDiffuseElastic::InitialiseOnFly    978 void G4NuclNuclDiffuseElastic::InitialiseOnFly(G4double Z, G4double A) 
980 {                                                 979 {
981   fAtomicNumber  = Z;     // atomic number        980   fAtomicNumber  = Z;     // atomic number
982   fAtomicWeight  = G4NistManager::Instance()->    981   fAtomicWeight  = G4NistManager::Instance()->GetAtomicMassAmu( static_cast< G4int >( Z ) );
983                                                   982 
984   G4double A1 = G4double( fParticle->GetBaryon    983   G4double A1 = G4double( fParticle->GetBaryonNumber() );
985   G4double R1 = CalculateNuclearRad(A1);          984   G4double R1 = CalculateNuclearRad(A1);
986                                                   985 
987   fNuclearRadius = CalculateNuclearRad(fAtomic    986   fNuclearRadius = CalculateNuclearRad(fAtomicWeight) + R1;
988                                                   987   
989   if( verboseLevel > 0 )                          988   if( verboseLevel > 0 )    
990   {                                               989   {
991     G4cout<<"G4NuclNuclDiffuseElastic::Initial    990     G4cout<<"G4NuclNuclDiffuseElastic::Initialise() the element with Z = "
992     <<Z<<"; and A = "<<A<<G4endl;                 991     <<Z<<"; and A = "<<A<<G4endl;
993   }                                               992   }
994   fElementNumberVector.push_back(fAtomicNumber    993   fElementNumberVector.push_back(fAtomicNumber);
995                                                   994 
996   BuildAngleTable();                              995   BuildAngleTable();
997                                                   996 
998   fAngleBank.push_back(fAngleTable);              997   fAngleBank.push_back(fAngleTable);
999                                                   998 
1000   return;                                        999   return;
1001 }                                                1000 }
1002                                                  1001 
1003 /////////////////////////////////////////////    1002 ///////////////////////////////////////////////////////////////////////////////
1004 //                                               1003 //
1005 // Build for given particle and element table    1004 // Build for given particle and element table of momentum, angle probability.
1006 // For the moment in lab system.                 1005 // For the moment in lab system. 
1007                                                  1006 
1008 void G4NuclNuclDiffuseElastic::BuildAngleTabl    1007 void G4NuclNuclDiffuseElastic::BuildAngleTable() 
1009 {                                                1008 {
1010   G4int i, j;                                    1009   G4int i, j;
1011   G4double partMom, kinE, m1 = fParticle->Get    1010   G4double partMom, kinE, m1 = fParticle->GetPDGMass();
1012   G4double alpha1, alpha2, alphaMax, alphaCou    1011   G4double alpha1, alpha2, alphaMax, alphaCoulomb, delta = 0., sum = 0.;
1013                                                  1012 
1014   // G4cout<<"particle z = "<<z<<"; particle     1013   // G4cout<<"particle z = "<<z<<"; particle m1 = "<<m1/GeV<<" GeV"<<G4endl;
1015                                                  1014 
1016   G4Integrator<G4NuclNuclDiffuseElastic,G4dou    1015   G4Integrator<G4NuclNuclDiffuseElastic,G4double(G4NuclNuclDiffuseElastic::*)(G4double)> integral;
1017                                                  1016   
1018   fAngleTable = new G4PhysicsTable(fEnergyBin    1017   fAngleTable = new G4PhysicsTable(fEnergyBin);
1019                                                  1018 
1020   for( i = 0; i < fEnergyBin; i++)               1019   for( i = 0; i < fEnergyBin; i++)
1021   {                                              1020   {
1022     kinE        = fEnergyVector->GetLowEdgeEn    1021     kinE        = fEnergyVector->GetLowEdgeEnergy(i);
1023                                                  1022 
1024     // G4cout<<G4endl;                           1023     // G4cout<<G4endl;
1025     // G4cout<<"kinE = "<<kinE/MeV<<" MeV"<<G    1024     // G4cout<<"kinE = "<<kinE/MeV<<" MeV"<<G4endl;
1026                                                  1025 
1027     partMom     = std::sqrt( kinE*(kinE + 2*m    1026     partMom     = std::sqrt( kinE*(kinE + 2*m1) );
1028                                                  1027 
1029     InitDynParameters(fParticle, partMom);       1028     InitDynParameters(fParticle, partMom);
1030                                                  1029 
1031     alphaMax = fRutherfordTheta*fCofAlphaMax;    1030     alphaMax = fRutherfordTheta*fCofAlphaMax;
1032                                                  1031 
1033     if(alphaMax > pi) alphaMax = pi;             1032     if(alphaMax > pi) alphaMax = pi;
1034                                                  1033 
1035     // VI: Coverity complain                     1034     // VI: Coverity complain
1036     //alphaMax = pi2;                            1035     //alphaMax = pi2;
1037                                                  1036 
1038     alphaCoulomb = fRutherfordTheta*fCofAlpha    1037     alphaCoulomb = fRutherfordTheta*fCofAlphaCoulomb;
1039                                                  1038 
1040     // G4cout<<"alphaCoulomb = "<<alphaCoulom    1039     // G4cout<<"alphaCoulomb = "<<alphaCoulomb/degree<<"; alphaMax = "<<alphaMax/degree<<G4endl;
1041                                                  1040 
1042     G4PhysicsFreeVector* angleVector = new G4    1041     G4PhysicsFreeVector* angleVector = new G4PhysicsFreeVector(fAngleBin-1);
1043                                                  1042 
1044     // G4PhysicsLogVector*  angleBins = new G    1043     // G4PhysicsLogVector*  angleBins = new G4PhysicsLogVector( 0.001*alphaMax, alphaMax, fAngleBin );
1045                                                  1044 
1046     G4double delth = (alphaMax-alphaCoulomb)/    1045     G4double delth = (alphaMax-alphaCoulomb)/fAngleBin;
1047                                                  1046         
1048     sum = 0.;                                    1047     sum = 0.;
1049                                                  1048 
1050     // fAddCoulomb = false;                      1049     // fAddCoulomb = false;
1051     fAddCoulomb = true;                          1050     fAddCoulomb = true;
1052                                                  1051 
1053     // for(j = 1; j < fAngleBin; j++)            1052     // for(j = 1; j < fAngleBin; j++)
1054     for(j = fAngleBin-1; j >= 1; j--)            1053     for(j = fAngleBin-1; j >= 1; j--)
1055     {                                            1054     {
1056       // alpha1 = angleBins->GetLowEdgeEnergy    1055       // alpha1 = angleBins->GetLowEdgeEnergy(j-1);
1057       // alpha2 = angleBins->GetLowEdgeEnergy    1056       // alpha2 = angleBins->GetLowEdgeEnergy(j);
1058                                                  1057 
1059       // alpha1 = alphaMax*(j-1)/fAngleBin;      1058       // alpha1 = alphaMax*(j-1)/fAngleBin;
1060       // alpha2 = alphaMax*( j )/fAngleBin;      1059       // alpha2 = alphaMax*( j )/fAngleBin;
1061                                                  1060 
1062       alpha1 = alphaCoulomb + delth*(j-1);       1061       alpha1 = alphaCoulomb + delth*(j-1);
1063       // if(alpha1 < kRlim2) alpha1 = kRlim2;    1062       // if(alpha1 < kRlim2) alpha1 = kRlim2;
1064       alpha2 = alpha1 + delth;                   1063       alpha2 = alpha1 + delth;
1065                                                  1064 
1066       delta = integral.Legendre10(this, &G4Nu    1065       delta = integral.Legendre10(this, &G4NuclNuclDiffuseElastic::GetFresnelIntegrandXsc, alpha1, alpha2);
1067       // delta = integral.Legendre96(this, &G    1066       // delta = integral.Legendre96(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, alpha1, alpha2);
1068                                                  1067 
1069       sum += delta;                              1068       sum += delta;
1070                                                  1069       
1071       angleVector->PutValue( j-1 , alpha1, su    1070       angleVector->PutValue( j-1 , alpha1, sum ); // alpha2
1072       // G4cout<<"j-1 = "<<j-1<<"; alpha2 = "    1071       // G4cout<<"j-1 = "<<j-1<<"; alpha2 = "<<alpha2/degree<<"; sum = "<<sum<<G4endl;
1073     }                                            1072     }
1074     fAngleTable->insertAt(i,angleVector);        1073     fAngleTable->insertAt(i,angleVector);
1075                                                  1074 
1076     // delete[] angleVector;                     1075     // delete[] angleVector; 
1077     // delete[] angleBins;                       1076     // delete[] angleBins; 
1078   }                                              1077   }
1079   return;                                        1078   return;
1080 }                                                1079 }
1081                                                  1080 
1082 /////////////////////////////////////////////    1081 /////////////////////////////////////////////////////////////////////////////////
1083 //                                               1082 //
1084 //                                               1083 //
1085                                                  1084 
1086 G4double                                         1085 G4double 
1087 G4NuclNuclDiffuseElastic:: GetScatteringAngle    1086 G4NuclNuclDiffuseElastic:: GetScatteringAngle( G4int iMomentum, G4int iAngle, G4double position )
1088 {                                                1087 {
1089  G4double x1, x2, y1, y2, randAngle;             1088  G4double x1, x2, y1, y2, randAngle;
1090                                                  1089 
1091   if( iAngle == 0 )                              1090   if( iAngle == 0 )
1092   {                                              1091   {
1093     randAngle = (*fAngleTable)(iMomentum)->Ge    1092     randAngle = (*fAngleTable)(iMomentum)->GetLowEdgeEnergy(iAngle);
1094     // iAngle++;                                 1093     // iAngle++;
1095   }                                              1094   }
1096   else                                           1095   else
1097   {                                              1096   {
1098     if ( iAngle >= G4int((*fAngleTable)(iMome    1097     if ( iAngle >= G4int((*fAngleTable)(iMomentum)->GetVectorLength()) )
1099     {                                            1098     {
1100       iAngle = G4int((*fAngleTable)(iMomentum << 1099       iAngle = (*fAngleTable)(iMomentum)->GetVectorLength() - 1;
1101     }                                            1100     }
1102     y1 = (*(*fAngleTable)(iMomentum))(iAngle-    1101     y1 = (*(*fAngleTable)(iMomentum))(iAngle-1);
1103     y2 = (*(*fAngleTable)(iMomentum))(iAngle)    1102     y2 = (*(*fAngleTable)(iMomentum))(iAngle);
1104                                                  1103 
1105     x1 = (*fAngleTable)(iMomentum)->GetLowEdg    1104     x1 = (*fAngleTable)(iMomentum)->GetLowEdgeEnergy(iAngle-1);
1106     x2 = (*fAngleTable)(iMomentum)->GetLowEdg    1105     x2 = (*fAngleTable)(iMomentum)->GetLowEdgeEnergy(iAngle);
1107                                                  1106 
1108     if ( x1 == x2 )   randAngle = x2;            1107     if ( x1 == x2 )   randAngle = x2;
1109     else                                         1108     else
1110     {                                            1109     {
1111       if ( y1 == y2 ) randAngle = x1 + ( x2 -    1110       if ( y1 == y2 ) randAngle = x1 + ( x2 - x1 )*G4UniformRand();
1112       else                                       1111       else
1113       {                                          1112       {
1114         randAngle = x1 + ( position - y1 )*(     1113         randAngle = x1 + ( position - y1 )*( x2 - x1 )/( y2 - y1 );
1115       }                                          1114       }
1116     }                                            1115     }
1117   }                                              1116   }
1118   return randAngle;                              1117   return randAngle;
1119 }                                                1118 }
1120                                                  1119 
1121                                                  1120 
1122                                                  1121 
1123 /////////////////////////////////////////////    1122 ////////////////////////////////////////////////////////////////////////////
1124 //                                               1123 //
1125 // Return scattering angle sampled in lab sys    1124 // Return scattering angle sampled in lab system (target at rest)
1126                                                  1125 
1127                                                  1126 
1128                                                  1127 
1129 G4double                                         1128 G4double 
1130 G4NuclNuclDiffuseElastic::SampleThetaLab( con    1129 G4NuclNuclDiffuseElastic::SampleThetaLab( const G4HadProjectile* aParticle, 
1131                                         G4dou    1130                                         G4double tmass, G4double A)
1132 {                                                1131 {
1133   const G4ParticleDefinition* theParticle = a    1132   const G4ParticleDefinition* theParticle = aParticle->GetDefinition();
1134   G4double m1 = theParticle->GetPDGMass();       1133   G4double m1 = theParticle->GetPDGMass();
1135   G4double plab = aParticle->GetTotalMomentum    1134   G4double plab = aParticle->GetTotalMomentum();
1136   G4LorentzVector lv1 = aParticle->Get4Moment    1135   G4LorentzVector lv1 = aParticle->Get4Momentum();
1137   G4LorentzVector lv(0.0,0.0,0.0,tmass);         1136   G4LorentzVector lv(0.0,0.0,0.0,tmass);   
1138   lv += lv1;                                     1137   lv += lv1;
1139                                                  1138 
1140   G4ThreeVector bst = lv.boostVector();          1139   G4ThreeVector bst = lv.boostVector();
1141   lv1.boost(-bst);                               1140   lv1.boost(-bst);
1142                                                  1141 
1143   G4ThreeVector p1 = lv1.vect();                 1142   G4ThreeVector p1 = lv1.vect();
1144   G4double ptot    = p1.mag();                   1143   G4double ptot    = p1.mag();
1145   G4double tmax    = 4.0*ptot*ptot;              1144   G4double tmax    = 4.0*ptot*ptot;
1146   G4double t       = 0.0;                        1145   G4double t       = 0.0;
1147                                                  1146 
1148                                                  1147 
1149   //                                             1148   //
1150   // Sample t                                    1149   // Sample t
1151   //                                             1150   //
1152                                                  1151   
1153   t = SampleT( theParticle, ptot, A);            1152   t = SampleT( theParticle, ptot, A);
1154                                                  1153 
1155   // NaN finder                                  1154   // NaN finder
1156   if(!(t < 0.0 || t >= 0.0))                     1155   if(!(t < 0.0 || t >= 0.0)) 
1157   {                                              1156   {
1158     if (verboseLevel > 0)                        1157     if (verboseLevel > 0) 
1159     {                                            1158     {
1160       G4cout << "G4NuclNuclDiffuseElastic:WAR    1159       G4cout << "G4NuclNuclDiffuseElastic:WARNING: A = " << A 
1161        << " mom(GeV)= " << plab/GeV              1160        << " mom(GeV)= " << plab/GeV 
1162              << " S-wave will be sampled"        1161              << " S-wave will be sampled" 
1163        << G4endl;                                1162        << G4endl; 
1164     }                                            1163     }
1165     t = G4UniformRand()*tmax;                    1164     t = G4UniformRand()*tmax; 
1166   }                                              1165   }
1167   if(verboseLevel>1)                             1166   if(verboseLevel>1)
1168   {                                              1167   {
1169     G4cout <<" t= " << t << " tmax= " << tmax    1168     G4cout <<" t= " << t << " tmax= " << tmax 
1170      << " ptot= " << ptot << G4endl;             1169      << " ptot= " << ptot << G4endl;
1171   }                                              1170   }
1172   // Sampling of angles in CM system             1171   // Sampling of angles in CM system
1173                                                  1172 
1174   G4double phi  = G4UniformRand()*twopi;         1173   G4double phi  = G4UniformRand()*twopi;
1175   G4double cost = 1. - 2.0*t/tmax;               1174   G4double cost = 1. - 2.0*t/tmax;
1176   G4double sint;                                 1175   G4double sint;
1177                                                  1176 
1178   if( cost >= 1.0 )                              1177   if( cost >= 1.0 ) 
1179   {                                              1178   {
1180     cost = 1.0;                                  1179     cost = 1.0;
1181     sint = 0.0;                                  1180     sint = 0.0;
1182   }                                              1181   }
1183   else if( cost <= -1.0)                         1182   else if( cost <= -1.0) 
1184   {                                              1183   {
1185     cost = -1.0;                                 1184     cost = -1.0;
1186     sint =  0.0;                                 1185     sint =  0.0;
1187   }                                              1186   }
1188   else                                           1187   else  
1189   {                                              1188   {
1190     sint = std::sqrt((1.0-cost)*(1.0+cost));     1189     sint = std::sqrt((1.0-cost)*(1.0+cost));
1191   }                                              1190   }    
1192   if (verboseLevel>1)                            1191   if (verboseLevel>1) 
1193   {                                              1192   {
1194     G4cout << "cos(t)=" << cost << " std::sin    1193     G4cout << "cos(t)=" << cost << " std::sin(t)=" << sint << G4endl;
1195   }                                              1194   }
1196   G4ThreeVector v1(sint*std::cos(phi),sint*st    1195   G4ThreeVector v1(sint*std::cos(phi),sint*std::sin(phi),cost);
1197   v1 *= ptot;                                    1196   v1 *= ptot;
1198   G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),s    1197   G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),std::sqrt(ptot*ptot + m1*m1));
1199                                                  1198 
1200   nlv1.boost(bst);                               1199   nlv1.boost(bst); 
1201                                                  1200 
1202   G4ThreeVector np1 = nlv1.vect();               1201   G4ThreeVector np1 = nlv1.vect();
1203                                                  1202 
1204     // G4double theta = std::acos( np1.z()/np    1203     // G4double theta = std::acos( np1.z()/np1.mag() );  // degree;
1205                                                  1204 
1206   G4double theta = np1.theta();                  1205   G4double theta = np1.theta();
1207                                                  1206 
1208   return theta;                                  1207   return theta;
1209 }                                                1208 }
1210                                                  1209 
1211 /////////////////////////////////////////////    1210 ////////////////////////////////////////////////////////////////////////////
1212 //                                               1211 //
1213 // Return scattering angle in lab system (tar    1212 // Return scattering angle in lab system (target at rest) knowing theta in CMS
1214                                                  1213 
1215                                                  1214 
1216                                                  1215 
1217 G4double                                         1216 G4double 
1218 G4NuclNuclDiffuseElastic::ThetaCMStoThetaLab(    1217 G4NuclNuclDiffuseElastic::ThetaCMStoThetaLab( const G4DynamicParticle* aParticle, 
1219                                         G4dou    1218                                         G4double tmass, G4double thetaCMS)
1220 {                                                1219 {
1221   const G4ParticleDefinition* theParticle = a    1220   const G4ParticleDefinition* theParticle = aParticle->GetDefinition();
1222   G4double m1 = theParticle->GetPDGMass();       1221   G4double m1 = theParticle->GetPDGMass();
1223   // G4double plab = aParticle->GetTotalMomen    1222   // G4double plab = aParticle->GetTotalMomentum();
1224   G4LorentzVector lv1 = aParticle->Get4Moment    1223   G4LorentzVector lv1 = aParticle->Get4Momentum();
1225   G4LorentzVector lv(0.0,0.0,0.0,tmass);         1224   G4LorentzVector lv(0.0,0.0,0.0,tmass);   
1226                                                  1225 
1227   lv += lv1;                                     1226   lv += lv1;
1228                                                  1227 
1229   G4ThreeVector bst = lv.boostVector();          1228   G4ThreeVector bst = lv.boostVector();
1230                                                  1229 
1231   lv1.boost(-bst);                               1230   lv1.boost(-bst);
1232                                                  1231 
1233   G4ThreeVector p1 = lv1.vect();                 1232   G4ThreeVector p1 = lv1.vect();
1234   G4double ptot    = p1.mag();                   1233   G4double ptot    = p1.mag();
1235                                                  1234 
1236   G4double phi  = G4UniformRand()*twopi;         1235   G4double phi  = G4UniformRand()*twopi;
1237   G4double cost = std::cos(thetaCMS);            1236   G4double cost = std::cos(thetaCMS);
1238   G4double sint;                                 1237   G4double sint;
1239                                                  1238 
1240   if( cost >= 1.0 )                              1239   if( cost >= 1.0 ) 
1241   {                                              1240   {
1242     cost = 1.0;                                  1241     cost = 1.0;
1243     sint = 0.0;                                  1242     sint = 0.0;
1244   }                                              1243   }
1245   else if( cost <= -1.0)                         1244   else if( cost <= -1.0) 
1246   {                                              1245   {
1247     cost = -1.0;                                 1246     cost = -1.0;
1248     sint =  0.0;                                 1247     sint =  0.0;
1249   }                                              1248   }
1250   else                                           1249   else  
1251   {                                              1250   {
1252     sint = std::sqrt((1.0-cost)*(1.0+cost));     1251     sint = std::sqrt((1.0-cost)*(1.0+cost));
1253   }                                              1252   }    
1254   if (verboseLevel>1)                            1253   if (verboseLevel>1) 
1255   {                                              1254   {
1256     G4cout << "cos(tcms)=" << cost << " std::    1255     G4cout << "cos(tcms)=" << cost << " std::sin(tcms)=" << sint << G4endl;
1257   }                                              1256   }
1258   G4ThreeVector v1(sint*std::cos(phi),sint*st    1257   G4ThreeVector v1(sint*std::cos(phi),sint*std::sin(phi),cost);
1259   v1 *= ptot;                                    1258   v1 *= ptot;
1260   G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),s    1259   G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),std::sqrt(ptot*ptot + m1*m1));
1261                                                  1260 
1262   nlv1.boost(bst);                               1261   nlv1.boost(bst); 
1263                                                  1262 
1264   G4ThreeVector np1 = nlv1.vect();               1263   G4ThreeVector np1 = nlv1.vect();
1265                                                  1264 
1266                                                  1265 
1267   G4double thetaLab = np1.theta();               1266   G4double thetaLab = np1.theta();
1268                                                  1267 
1269   return thetaLab;                               1268   return thetaLab;
1270 }                                                1269 }
1271                                                  1270 
1272 /////////////////////////////////////////////    1271 ////////////////////////////////////////////////////////////////////////////
1273 //                                               1272 //
1274 // Return scattering angle in CMS system (tar    1273 // Return scattering angle in CMS system (target at rest) knowing theta in Lab
1275                                                  1274 
1276                                                  1275 
1277                                                  1276 
1278 G4double                                         1277 G4double 
1279 G4NuclNuclDiffuseElastic::ThetaLabToThetaCMS(    1278 G4NuclNuclDiffuseElastic::ThetaLabToThetaCMS( const G4DynamicParticle* aParticle, 
1280                                         G4dou    1279                                         G4double tmass, G4double thetaLab)
1281 {                                                1280 {
1282   const G4ParticleDefinition* theParticle = a    1281   const G4ParticleDefinition* theParticle = aParticle->GetDefinition();
1283   G4double m1 = theParticle->GetPDGMass();       1282   G4double m1 = theParticle->GetPDGMass();
1284   G4double plab = aParticle->GetTotalMomentum    1283   G4double plab = aParticle->GetTotalMomentum();
1285   G4LorentzVector lv1 = aParticle->Get4Moment    1284   G4LorentzVector lv1 = aParticle->Get4Momentum();
1286   G4LorentzVector lv(0.0,0.0,0.0,tmass);         1285   G4LorentzVector lv(0.0,0.0,0.0,tmass);   
1287                                                  1286 
1288   lv += lv1;                                     1287   lv += lv1;
1289                                                  1288 
1290   G4ThreeVector bst = lv.boostVector();          1289   G4ThreeVector bst = lv.boostVector();
1291                                                  1290 
1292   // lv1.boost(-bst);                            1291   // lv1.boost(-bst);
1293                                                  1292 
1294   // G4ThreeVector p1 = lv1.vect();              1293   // G4ThreeVector p1 = lv1.vect();
1295   // G4double ptot    = p1.mag();                1294   // G4double ptot    = p1.mag();
1296                                                  1295 
1297   G4double phi  = G4UniformRand()*twopi;         1296   G4double phi  = G4UniformRand()*twopi;
1298   G4double cost = std::cos(thetaLab);            1297   G4double cost = std::cos(thetaLab);
1299   G4double sint;                                 1298   G4double sint;
1300                                                  1299 
1301   if( cost >= 1.0 )                              1300   if( cost >= 1.0 ) 
1302   {                                              1301   {
1303     cost = 1.0;                                  1302     cost = 1.0;
1304     sint = 0.0;                                  1303     sint = 0.0;
1305   }                                              1304   }
1306   else if( cost <= -1.0)                         1305   else if( cost <= -1.0) 
1307   {                                              1306   {
1308     cost = -1.0;                                 1307     cost = -1.0;
1309     sint =  0.0;                                 1308     sint =  0.0;
1310   }                                              1309   }
1311   else                                           1310   else  
1312   {                                              1311   {
1313     sint = std::sqrt((1.0-cost)*(1.0+cost));     1312     sint = std::sqrt((1.0-cost)*(1.0+cost));
1314   }                                              1313   }    
1315   if (verboseLevel>1)                            1314   if (verboseLevel>1) 
1316   {                                              1315   {
1317     G4cout << "cos(tlab)=" << cost << " std::    1316     G4cout << "cos(tlab)=" << cost << " std::sin(tlab)=" << sint << G4endl;
1318   }                                              1317   }
1319   G4ThreeVector v1(sint*std::cos(phi),sint*st    1318   G4ThreeVector v1(sint*std::cos(phi),sint*std::sin(phi),cost);
1320   v1 *= plab;                                    1319   v1 *= plab;
1321   G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),s    1320   G4LorentzVector nlv1(v1.x(),v1.y(),v1.z(),std::sqrt(plab*plab + m1*m1));
1322                                                  1321 
1323   nlv1.boost(-bst);                              1322   nlv1.boost(-bst); 
1324                                                  1323 
1325   G4ThreeVector np1 = nlv1.vect();               1324   G4ThreeVector np1 = nlv1.vect();
1326                                                  1325 
1327                                                  1326 
1328   G4double thetaCMS = np1.theta();               1327   G4double thetaCMS = np1.theta();
1329                                                  1328 
1330   return thetaCMS;                               1329   return thetaCMS;
1331 }                                                1330 }
1332                                                  1331 
1333 /////////////////////////////////////////////    1332 ///////////////////////////////////////////////////////////////////////////////
1334 //                                               1333 //
1335 // Test for given particle and element table     1334 // Test for given particle and element table of momentum, angle probability.
1336 // For the moment in lab system.                 1335 // For the moment in lab system. 
1337                                                  1336 
1338 void G4NuclNuclDiffuseElastic::TestAngleTable    1337 void G4NuclNuclDiffuseElastic::TestAngleTable(const G4ParticleDefinition* theParticle, G4double partMom,
1339                                             G    1338                                             G4double Z, G4double A) 
1340 {                                                1339 {
1341   fAtomicNumber  = Z;     // atomic number       1340   fAtomicNumber  = Z;     // atomic number
1342   fAtomicWeight  = A;     // number of nucleo    1341   fAtomicWeight  = A;     // number of nucleons
1343   fNuclearRadius = CalculateNuclearRad(fAtomi    1342   fNuclearRadius = CalculateNuclearRad(fAtomicWeight);
1344                                                  1343   
1345                                                  1344      
1346                                                  1345   
1347   G4cout<<"G4NuclNuclDiffuseElastic::TestAngl    1346   G4cout<<"G4NuclNuclDiffuseElastic::TestAngleTable() init the element with Z = "
1348     <<Z<<"; and A = "<<A<<G4endl;                1347     <<Z<<"; and A = "<<A<<G4endl;
1349                                                  1348  
1350   fElementNumberVector.push_back(fAtomicNumbe    1349   fElementNumberVector.push_back(fAtomicNumber);
1351                                                  1350 
1352                                                  1351  
1353                                                  1352 
1354                                                  1353 
1355   G4int i=0, j;                                  1354   G4int i=0, j;
1356   G4double a = 0., z = theParticle->GetPDGCha    1355   G4double a = 0., z = theParticle->GetPDGCharge(),  m1 = fParticle->GetPDGMass();
1357   G4double alpha1=0., alpha2=0., alphaMax=0.,    1356   G4double alpha1=0., alpha2=0., alphaMax=0., alphaCoulomb=0.;
1358   G4double deltaL10 = 0., deltaL96 = 0., delt    1357   G4double deltaL10 = 0., deltaL96 = 0., deltaAG = 0.;
1359   G4double sumL10 = 0.,sumL96 = 0.,sumAG = 0.    1358   G4double sumL10 = 0.,sumL96 = 0.,sumAG = 0.;
1360   G4double epsilon = 0.001;                      1359   G4double epsilon = 0.001;
1361                                                  1360 
1362   G4Integrator<G4NuclNuclDiffuseElastic,G4dou    1361   G4Integrator<G4NuclNuclDiffuseElastic,G4double(G4NuclNuclDiffuseElastic::*)(G4double)> integral;
1363                                                  1362   
1364   fAngleTable = new G4PhysicsTable(fEnergyBin    1363   fAngleTable = new G4PhysicsTable(fEnergyBin);
1365                                                  1364 
1366   fWaveVector = partMom/hbarc;                   1365   fWaveVector = partMom/hbarc;
1367                                                  1366 
1368   G4double kR     = fWaveVector*fNuclearRadiu    1367   G4double kR     = fWaveVector*fNuclearRadius;
1369   G4double kR2    = kR*kR;                       1368   G4double kR2    = kR*kR;
1370   G4double kRmax  = 10.6; // 10.6, 18, 10.174    1369   G4double kRmax  = 10.6; // 10.6, 18, 10.174; ~ 3 maxima of J1 or 15., 25.
1371   G4double kRcoul = 1.2; // 1.4, 2.5; // on t    1370   G4double kRcoul = 1.2; // 1.4, 2.5; // on the first slope of J1
1372                                                  1371 
1373   alphaMax = kRmax*kRmax/kR2;                    1372   alphaMax = kRmax*kRmax/kR2;
1374                                                  1373 
1375   if (alphaMax > 4.) alphaMax = 4.;  // vmg05    1374   if (alphaMax > 4.) alphaMax = 4.;  // vmg05-02-09: was pi2 
1376                                                  1375 
1377   alphaCoulomb = kRcoul*kRcoul/kR2;              1376   alphaCoulomb = kRcoul*kRcoul/kR2;
1378                                                  1377 
1379   if( z )                                        1378   if( z )
1380   {                                              1379   {
1381       a           = partMom/m1; // beta*gamma    1380       a           = partMom/m1; // beta*gamma for m1
1382       fBeta       = a/std::sqrt(1+a*a);          1381       fBeta       = a/std::sqrt(1+a*a);
1383       fZommerfeld = CalculateZommerfeld( fBet    1382       fZommerfeld = CalculateZommerfeld( fBeta, z, fAtomicNumber);
1384       fAm         = CalculateAm( partMom, fZo    1383       fAm         = CalculateAm( partMom, fZommerfeld, fAtomicNumber);
1385   }                                              1384   }
1386   G4PhysicsFreeVector* angleVector = new G4Ph    1385   G4PhysicsFreeVector* angleVector = new G4PhysicsFreeVector(fAngleBin-1);
1387                                                  1386 
1388   // G4PhysicsLogVector*  angleBins = new G4P    1387   // G4PhysicsLogVector*  angleBins = new G4PhysicsLogVector( 0.001*alphaMax, alphaMax, fAngleBin );
1389                                                  1388     
1390                                                  1389   
1391   fAddCoulomb = false;                           1390   fAddCoulomb = false;
1392                                                  1391 
1393   for(j = 1; j < fAngleBin; j++)                 1392   for(j = 1; j < fAngleBin; j++)
1394   {                                              1393   {
1395       // alpha1 = angleBins->GetLowEdgeEnergy    1394       // alpha1 = angleBins->GetLowEdgeEnergy(j-1);
1396       // alpha2 = angleBins->GetLowEdgeEnergy    1395       // alpha2 = angleBins->GetLowEdgeEnergy(j);
1397                                                  1396 
1398     alpha1 = alphaMax*(j-1)/fAngleBin;           1397     alpha1 = alphaMax*(j-1)/fAngleBin;
1399     alpha2 = alphaMax*( j )/fAngleBin;           1398     alpha2 = alphaMax*( j )/fAngleBin;
1400                                                  1399 
1401     if( ( alpha2 > alphaCoulomb ) && z ) fAdd    1400     if( ( alpha2 > alphaCoulomb ) && z ) fAddCoulomb = true;
1402                                                  1401 
1403     deltaL10 = integral.Legendre10(this, &G4N    1402     deltaL10 = integral.Legendre10(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, alpha1, alpha2);
1404     deltaL96 = integral.Legendre96(this, &G4N    1403     deltaL96 = integral.Legendre96(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, alpha1, alpha2);
1405     deltaAG  = integral.AdaptiveGauss(this, &    1404     deltaAG  = integral.AdaptiveGauss(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, 
1406                                        alpha1    1405                                        alpha1, alpha2,epsilon);
1407                                                  1406 
1408       // G4cout<<alpha1<<"\t"<<std::sqrt(alph    1407       // G4cout<<alpha1<<"\t"<<std::sqrt(alpha1)/degree<<"\t"
1409       //     <<deltaL10<<"\t"<<deltaL96<<"\t"    1408       //     <<deltaL10<<"\t"<<deltaL96<<"\t"<<deltaAG<<G4endl;
1410                                                  1409 
1411     sumL10 += deltaL10;                          1410     sumL10 += deltaL10;
1412     sumL96 += deltaL96;                          1411     sumL96 += deltaL96;
1413     sumAG  += deltaAG;                           1412     sumAG  += deltaAG;
1414                                                  1413 
1415     G4cout<<alpha1<<"\t"<<std::sqrt(alpha1)/d    1414     G4cout<<alpha1<<"\t"<<std::sqrt(alpha1)/degree<<"\t"
1416             <<sumL10<<"\t"<<sumL96<<"\t"<<sum    1415             <<sumL10<<"\t"<<sumL96<<"\t"<<sumAG<<G4endl;
1417                                                  1416       
1418     angleVector->PutValue( j-1 , alpha1, sumL    1417     angleVector->PutValue( j-1 , alpha1, sumL10 ); // alpha2
1419   }                                              1418   }
1420   fAngleTable->insertAt(i,angleVector);          1419   fAngleTable->insertAt(i,angleVector);
1421   fAngleBank.push_back(fAngleTable);             1420   fAngleBank.push_back(fAngleTable);
1422                                                  1421 
1423   /*                                             1422   /*
1424   // Integral over all angle range - Bad accu    1423   // Integral over all angle range - Bad accuracy !!!
1425                                                  1424 
1426   sumL10 = integral.Legendre10(this, &G4NuclN    1425   sumL10 = integral.Legendre10(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, 0., alpha2);
1427   sumL96 = integral.Legendre96(this, &G4NuclN    1426   sumL96 = integral.Legendre96(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, 0., alpha2);
1428   sumAG  = integral.AdaptiveGauss(this, &G4Nu    1427   sumAG  = integral.AdaptiveGauss(this, &G4NuclNuclDiffuseElastic::GetIntegrandFunction, 
1429                                        0., al    1428                                        0., alpha2,epsilon);
1430   G4cout<<G4endl;                                1429   G4cout<<G4endl;
1431   G4cout<<alpha2<<"\t"<<std::sqrt(alpha2)/deg    1430   G4cout<<alpha2<<"\t"<<std::sqrt(alpha2)/degree<<"\t"
1432             <<sumL10<<"\t"<<sumL96<<"\t"<<sum    1431             <<sumL10<<"\t"<<sumL96<<"\t"<<sumAG<<G4endl;
1433   */                                             1432   */
1434   return;                                        1433   return;
1435 }                                                1434 }
1436                                                  1435 
1437 /////////////////////////////////////////////    1436 /////////////////////////////////////////////////////////////////
1438 //                                               1437 //
1439 //                                               1438 //
1440                                                  1439 
1441  G4double G4NuclNuclDiffuseElastic::GetLegend    1440  G4double G4NuclNuclDiffuseElastic::GetLegendrePol(G4int n, G4double theta)
1442 {                                                1441 {
1443   G4double legPol, epsilon = 1.e-6;              1442   G4double legPol, epsilon = 1.e-6;
1444   G4double x = std::cos(theta);                  1443   G4double x = std::cos(theta);
1445                                                  1444 
1446   if     ( n  < 0 ) legPol = 0.;                 1445   if     ( n  < 0 ) legPol = 0.;
1447   else if( n == 0 ) legPol = 1.;                 1446   else if( n == 0 ) legPol = 1.;
1448   else if( n == 1 ) legPol = x;                  1447   else if( n == 1 ) legPol = x;
1449   else if( n == 2 ) legPol = (3.*x*x-1.)/2.;     1448   else if( n == 2 ) legPol = (3.*x*x-1.)/2.;
1450   else if( n == 3 ) legPol = (5.*x*x*x-3.*x)/    1449   else if( n == 3 ) legPol = (5.*x*x*x-3.*x)/2.;
1451   else if( n == 4 ) legPol = (35.*x*x*x*x-30.    1450   else if( n == 4 ) legPol = (35.*x*x*x*x-30.*x*x+3.)/8.;
1452   else if( n == 5 ) legPol = (63.*x*x*x*x*x-7    1451   else if( n == 5 ) legPol = (63.*x*x*x*x*x-70.*x*x*x+15.*x)/8.;
1453   else if( n == 6 ) legPol = (231.*x*x*x*x*x*    1452   else if( n == 6 ) legPol = (231.*x*x*x*x*x*x-315.*x*x*x*x+105.*x*x-5.)/16.;
1454   else                                           1453   else           
1455   {                                              1454   {
1456     // legPol = ( (2*n-1)*x*GetLegendrePol(n-    1455     // legPol = ( (2*n-1)*x*GetLegendrePol(n-1,x) - (n-1)*GetLegendrePol(n-2,x) )/n;
1457                                                  1456 
1458     legPol = std::sqrt( 2./(n*CLHEP::pi*std::    1457     legPol = std::sqrt( 2./(n*CLHEP::pi*std::sin(theta+epsilon)) )*std::sin( (n+0.5)*theta+0.25*CLHEP::pi );
1459   }                                              1458   }
1460   return legPol;                                 1459   return legPol; 
1461 }                                                1460 }
1462                                                  1461 
1463 /////////////////////////////////////////////    1462 /////////////////////////////////////////////////////////////////
1464 //                                               1463 //
1465 //                                               1464 //
1466                                                  1465 
1467 G4complex G4NuclNuclDiffuseElastic::GetErfCom    1466 G4complex G4NuclNuclDiffuseElastic::GetErfComp(G4complex z, G4int nMax)
1468 {                                                1467 {
1469   G4int n;                                       1468   G4int n;
1470   G4double n2, cofn, shny, chny, fn, gn;         1469   G4double n2, cofn, shny, chny, fn, gn;
1471                                                  1470 
1472   G4double x = z.real();                         1471   G4double x = z.real();
1473   G4double y = z.imag();                         1472   G4double y = z.imag();
1474                                                  1473 
1475   G4double outRe = 0., outIm = 0.;               1474   G4double outRe = 0., outIm = 0.;
1476                                                  1475 
1477   G4double twox  = 2.*x;                         1476   G4double twox  = 2.*x;
1478   G4double twoxy = twox*y;                       1477   G4double twoxy = twox*y;
1479   G4double twox2 = twox*twox;                    1478   G4double twox2 = twox*twox;
1480                                                  1479 
1481   G4double cof1 = G4Exp(-x*x)/CLHEP::pi;         1480   G4double cof1 = G4Exp(-x*x)/CLHEP::pi;
1482                                                  1481 
1483   G4double cos2xy = std::cos(twoxy);             1482   G4double cos2xy = std::cos(twoxy);
1484   G4double sin2xy = std::sin(twoxy);             1483   G4double sin2xy = std::sin(twoxy);
1485                                                  1484 
1486   G4double twoxcos2xy = twox*cos2xy;             1485   G4double twoxcos2xy = twox*cos2xy;
1487   G4double twoxsin2xy = twox*sin2xy;             1486   G4double twoxsin2xy = twox*sin2xy;
1488                                                  1487 
1489   for( n = 1; n <= nMax; n++)                    1488   for( n = 1; n <= nMax; n++)
1490   {                                              1489   {
1491     n2   = n*n;                                  1490     n2   = n*n;
1492                                                  1491 
1493     cofn = G4Exp(-0.5*n2)/(n2+twox2);  // /(n    1492     cofn = G4Exp(-0.5*n2)/(n2+twox2);  // /(n2+0.5*twox2);
1494                                                  1493 
1495     chny = std::cosh(n*y);                       1494     chny = std::cosh(n*y);
1496     shny = std::sinh(n*y);                       1495     shny = std::sinh(n*y);
1497                                                  1496 
1498     fn  = twox - twoxcos2xy*chny + n*sin2xy*s    1497     fn  = twox - twoxcos2xy*chny + n*sin2xy*shny;
1499     gn  =        twoxsin2xy*chny + n*cos2xy*s    1498     gn  =        twoxsin2xy*chny + n*cos2xy*shny;
1500                                                  1499 
1501     fn *= cofn;                                  1500     fn *= cofn;
1502     gn *= cofn;                                  1501     gn *= cofn;
1503                                                  1502 
1504     outRe += fn;                                 1503     outRe += fn;
1505     outIm += gn;                                 1504     outIm += gn;
1506   }                                              1505   }
1507   outRe *= 2*cof1;                               1506   outRe *= 2*cof1;
1508   outIm *= 2*cof1;                               1507   outIm *= 2*cof1;
1509                                                  1508 
1510   if(std::abs(x) < 0.0001)                       1509   if(std::abs(x) < 0.0001)
1511   {                                              1510   {
1512     outRe += GetErf(x);                          1511     outRe += GetErf(x);
1513     outIm += cof1*y;                             1512     outIm += cof1*y;
1514   }                                              1513   }
1515   else                                           1514   else
1516   {                                              1515   {
1517     outRe += GetErf(x) + cof1*(1-cos2xy)/twox    1516     outRe += GetErf(x) + cof1*(1-cos2xy)/twox;
1518     outIm += cof1*sin2xy/twox;                   1517     outIm += cof1*sin2xy/twox;
1519   }                                              1518   }
1520   return G4complex(outRe, outIm);                1519   return G4complex(outRe, outIm);
1521 }                                                1520 }
1522                                                  1521 
1523                                                  1522 
1524 /////////////////////////////////////////////    1523 /////////////////////////////////////////////////////////////////
1525 //                                               1524 //
1526 //                                               1525 //
1527                                                  1526 
1528 G4complex G4NuclNuclDiffuseElastic::GetErfInt    1527 G4complex G4NuclNuclDiffuseElastic::GetErfInt(G4complex z) // , G4int nMax)
1529 {                                                1528 {
1530   G4double outRe, outIm;                         1529   G4double outRe, outIm;
1531                                                  1530 
1532   G4double x = z.real();                         1531   G4double x = z.real();
1533   G4double y = z.imag();                         1532   G4double y = z.imag();
1534   fReZ       = x;                                1533   fReZ       = x;
1535                                                  1534 
1536   G4Integrator<G4NuclNuclDiffuseElastic,G4dou    1535   G4Integrator<G4NuclNuclDiffuseElastic,G4double(G4NuclNuclDiffuseElastic::*)(G4double)> integral;
1537                                                  1536 
1538   outRe = integral.Legendre96(this,&G4NuclNuc    1537   outRe = integral.Legendre96(this,&G4NuclNuclDiffuseElastic::GetExpSin, 0., y );
1539   outIm = integral.Legendre96(this,&G4NuclNuc    1538   outIm = integral.Legendre96(this,&G4NuclNuclDiffuseElastic::GetExpCos, 0., y );
1540                                                  1539 
1541   outRe *= 2./std::sqrt(CLHEP::pi);              1540   outRe *= 2./std::sqrt(CLHEP::pi);
1542   outIm *= 2./std::sqrt(CLHEP::pi);              1541   outIm *= 2./std::sqrt(CLHEP::pi);
1543                                                  1542 
1544   outRe += GetErf(x);                            1543   outRe += GetErf(x);
1545                                                  1544 
1546   return G4complex(outRe, outIm);                1545   return G4complex(outRe, outIm);
1547 }                                                1546 }
1548                                                  1547 
1549 /////////////////////////////////////////////    1548 /////////////////////////////////////////////////////////////////
1550 //                                               1549 //
1551 //                                               1550 //
1552                                                  1551 
1553                                                  1552 
1554 G4complex G4NuclNuclDiffuseElastic::GammaLess    1553 G4complex G4NuclNuclDiffuseElastic::GammaLess(G4double theta)
1555 {                                                1554 {
1556   G4double sinThetaR      = 2.*fHalfRutThetaT    1555   G4double sinThetaR      = 2.*fHalfRutThetaTg/(1. + fHalfRutThetaTg2);
1557   G4double cosHalfThetaR2 = 1./(1. + fHalfRut    1556   G4double cosHalfThetaR2 = 1./(1. + fHalfRutThetaTg2);
1558                                                  1557 
1559   G4double u              = std::sqrt(0.5*fPr    1558   G4double u              = std::sqrt(0.5*fProfileLambda/sinThetaR);
1560   G4double kappa          = u/std::sqrt(CLHEP    1559   G4double kappa          = u/std::sqrt(CLHEP::pi);
1561   G4double dTheta         = theta - fRutherfo    1560   G4double dTheta         = theta - fRutherfordTheta;
1562   u                      *= dTheta;              1561   u                      *= dTheta;
1563   G4double u2             = u*u;                 1562   G4double u2             = u*u;
1564   G4double u2m2p3         = u2*2./3.;            1563   G4double u2m2p3         = u2*2./3.;
1565                                                  1564 
1566   G4complex im            = G4complex(0.,1.);    1565   G4complex im            = G4complex(0.,1.);
1567   G4complex order         = G4complex(u,u);      1566   G4complex order         = G4complex(u,u);
1568   order                  /= std::sqrt(2.);       1567   order                  /= std::sqrt(2.);
1569                                                  1568 
1570   G4complex gamma         = CLHEP::pi*kappa*G    1569   G4complex gamma         = CLHEP::pi*kappa*GetErfcInt(-order)*std::exp(im*(u*u+0.25*CLHEP::pi));
1571   G4complex a0            = 0.5*(1. + 4.*(1.+    1570   G4complex a0            = 0.5*(1. + 4.*(1.+im*u2)*cosHalfThetaR2/3.)/sinThetaR;
1572   G4complex a1            = 0.5*(1. + 2.*(1.+    1571   G4complex a1            = 0.5*(1. + 2.*(1.+im*u2m2p3)*cosHalfThetaR2)/sinThetaR;
1573   G4complex out           = gamma*(1. - a1*dT    1572   G4complex out           = gamma*(1. - a1*dTheta) - a0;
1574                                                  1573 
1575   return out;                                    1574   return out;
1576 }                                                1575 }
1577                                                  1576 
1578 /////////////////////////////////////////////    1577 /////////////////////////////////////////////////////////////////
1579 //                                               1578 //
1580 //                                               1579 //
1581                                                  1580 
1582 G4complex G4NuclNuclDiffuseElastic::GammaMore    1581 G4complex G4NuclNuclDiffuseElastic::GammaMore(G4double theta)
1583 {                                                1582 {
1584   G4double sinThetaR      = 2.*fHalfRutThetaT    1583   G4double sinThetaR      = 2.*fHalfRutThetaTg/(1. + fHalfRutThetaTg2);
1585   G4double cosHalfThetaR2 = 1./(1. + fHalfRut    1584   G4double cosHalfThetaR2 = 1./(1. + fHalfRutThetaTg2);
1586                                                  1585 
1587   G4double u              = std::sqrt(0.5*fPr    1586   G4double u              = std::sqrt(0.5*fProfileLambda/sinThetaR);
1588   G4double kappa          = u/std::sqrt(CLHEP    1587   G4double kappa          = u/std::sqrt(CLHEP::pi);
1589   G4double dTheta         = theta - fRutherfo    1588   G4double dTheta         = theta - fRutherfordTheta;
1590   u                      *= dTheta;              1589   u                      *= dTheta;
1591   G4double u2             = u*u;                 1590   G4double u2             = u*u;
1592   G4double u2m2p3         = u2*2./3.;            1591   G4double u2m2p3         = u2*2./3.;
1593                                                  1592 
1594   G4complex im            = G4complex(0.,1.);    1593   G4complex im            = G4complex(0.,1.);
1595   G4complex order         = G4complex(u,u);      1594   G4complex order         = G4complex(u,u);
1596   order                  /= std::sqrt(2.);       1595   order                  /= std::sqrt(2.);
1597   G4complex gamma         = CLHEP::pi*kappa*G    1596   G4complex gamma         = CLHEP::pi*kappa*GetErfcInt(order)*std::exp(im*(u*u+0.25*CLHEP::pi));
1598   G4complex a0            = 0.5*(1. + 4.*(1.+    1597   G4complex a0            = 0.5*(1. + 4.*(1.+im*u2)*cosHalfThetaR2/3.)/sinThetaR;
1599   G4complex a1            = 0.5*(1. + 2.*(1.+    1598   G4complex a1            = 0.5*(1. + 2.*(1.+im*u2m2p3)*cosHalfThetaR2)/sinThetaR;
1600   G4complex out           = -gamma*(1. - a1*d    1599   G4complex out           = -gamma*(1. - a1*dTheta) - a0;
1601                                                  1600 
1602   return out;                                    1601   return out;
1603 }                                                1602 }
1604                                                  1603 
1605 /////////////////////////////////////////////    1604 /////////////////////////////////////////////////////////////////
1606 //                                               1605 //
1607 //                                               1606 //
1608                                                  1607 
1609  G4complex G4NuclNuclDiffuseElastic::Amplitud    1608  G4complex G4NuclNuclDiffuseElastic::AmplitudeNear(G4double theta)
1610 {                                                1609 {
1611   G4double kappa = std::sqrt(0.5*fProfileLamb    1610   G4double kappa = std::sqrt(0.5*fProfileLambda/std::sin(theta)/CLHEP::pi);
1612   G4complex out = G4complex(kappa/fWaveVector    1611   G4complex out = G4complex(kappa/fWaveVector,0.);
1613                                                  1612 
1614   out *= PhaseNear(theta);                       1613   out *= PhaseNear(theta);
1615                                                  1614 
1616   if( theta <= fRutherfordTheta )                1615   if( theta <= fRutherfordTheta )
1617   {                                              1616   {
1618     out *= GammaLess(theta) + ProfileNear(the    1617     out *= GammaLess(theta) + ProfileNear(theta);
1619     // out *= GammaMore(theta) + ProfileNear(    1618     // out *= GammaMore(theta) + ProfileNear(theta);
1620     out += CoulombAmplitude(theta);              1619     out += CoulombAmplitude(theta);
1621   }                                              1620   }
1622   else                                           1621   else
1623   {                                              1622   {
1624     out *= GammaMore(theta) + ProfileNear(the    1623     out *= GammaMore(theta) + ProfileNear(theta);
1625     // out *= GammaLess(theta) + ProfileNear(    1624     // out *= GammaLess(theta) + ProfileNear(theta);
1626   }                                              1625   }
1627   return out;                                    1626   return out;
1628 }                                                1627 }
1629                                                  1628 
1630 /////////////////////////////////////////////    1629 /////////////////////////////////////////////////////////////////
1631 //                                               1630 //
1632 //                                               1631 //
1633                                                  1632 
1634 G4complex G4NuclNuclDiffuseElastic::Amplitude    1633 G4complex G4NuclNuclDiffuseElastic::AmplitudeSim(G4double theta)
1635 {                                                1634 {
1636   G4double sinThetaR  = 2.*fHalfRutThetaTg/(1    1635   G4double sinThetaR  = 2.*fHalfRutThetaTg/(1. + fHalfRutThetaTg2);
1637   G4double dTheta     = 0.5*(theta - fRutherf    1636   G4double dTheta     = 0.5*(theta - fRutherfordTheta);
1638   G4double sindTheta  = std::sin(dTheta);        1637   G4double sindTheta  = std::sin(dTheta);
1639   G4double persqrt2   = std::sqrt(0.5);          1638   G4double persqrt2   = std::sqrt(0.5);
1640                                                  1639 
1641   G4complex order     = G4complex(persqrt2,pe    1640   G4complex order     = G4complex(persqrt2,persqrt2);
1642   order              *= std::sqrt(0.5*fProfil    1641   order              *= std::sqrt(0.5*fProfileLambda/sinThetaR)*2.*sindTheta;
1643   // order              *= std::sqrt(0.5*fPro    1642   // order              *= std::sqrt(0.5*fProfileLambda/sinThetaR)*2.*dTheta;
1644                                                  1643 
1645   G4complex out;                                 1644   G4complex out;
1646                                                  1645 
1647   if ( theta <= fRutherfordTheta )               1646   if ( theta <= fRutherfordTheta )
1648   {                                              1647   {
1649     out = 1. - 0.5*GetErfcInt(-order)*Profile    1648     out = 1. - 0.5*GetErfcInt(-order)*ProfileNear(theta);
1650   }                                              1649   }
1651   else                                           1650   else
1652   {                                              1651   {
1653     out = 0.5*GetErfcInt(order)*ProfileNear(t    1652     out = 0.5*GetErfcInt(order)*ProfileNear(theta);
1654   }                                              1653   }
1655                                                  1654 
1656   out *= CoulombAmplitude(theta);                1655   out *= CoulombAmplitude(theta);
1657                                                  1656 
1658   return out;                                    1657   return out;
1659 }                                                1658 }
1660                                                  1659 
1661 /////////////////////////////////////////////    1660 /////////////////////////////////////////////////////////////////
1662 //                                               1661 //
1663 //                                               1662 //
1664                                                  1663 
1665  G4complex G4NuclNuclDiffuseElastic::Amplitud    1664  G4complex G4NuclNuclDiffuseElastic::AmplitudeGla(G4double theta)
1666 {                                                1665 {
1667   G4int n;                                       1666   G4int n;
1668   G4double T12b, b, b2; // cosTheta = std::co    1667   G4double T12b, b, b2; // cosTheta = std::cos(theta);
1669   G4complex out = G4complex(0.,0.), shiftC, s    1668   G4complex out = G4complex(0.,0.), shiftC, shiftN; 
1670   G4complex im  = G4complex(0.,1.);              1669   G4complex im  = G4complex(0.,1.);
1671                                                  1670 
1672   for( n = 0; n < fMaxL; n++)                    1671   for( n = 0; n < fMaxL; n++)
1673   {                                              1672   {
1674     shiftC = std::exp( im*2.*CalculateCoulomb    1673     shiftC = std::exp( im*2.*CalculateCoulombPhase(n) );
1675     // b = ( fZommerfeld + std::sqrt( fZommer    1674     // b = ( fZommerfeld + std::sqrt( fZommerfeld*fZommerfeld + n*(n+1) ) )/fWaveVector;
1676     b = ( std::sqrt( G4double(n*(n+1)) ) )/fW    1675     b = ( std::sqrt( G4double(n*(n+1)) ) )/fWaveVector;
1677     b2 = b*b;                                    1676     b2 = b*b;
1678     T12b = fSumSigma*G4Exp(-b2/fNuclearRadius    1677     T12b = fSumSigma*G4Exp(-b2/fNuclearRadiusSquare)/CLHEP::pi/fNuclearRadiusSquare;         
1679     shiftN = std::exp( -0.5*(1.-im*fEtaRatio)    1678     shiftN = std::exp( -0.5*(1.-im*fEtaRatio)*T12b ) - 1.;
1680     out +=  (2.*n+1.)*shiftC*shiftN*GetLegend    1679     out +=  (2.*n+1.)*shiftC*shiftN*GetLegendrePol(n, theta);   
1681   }                                              1680   }
1682   out /= 2.*im*fWaveVector;                      1681   out /= 2.*im*fWaveVector;
1683   out += CoulombAmplitude(theta);                1682   out += CoulombAmplitude(theta);
1684   return out;                                    1683   return out;
1685 }                                                1684 }
1686                                                  1685 
1687                                                  1686 
1688 /////////////////////////////////////////////    1687 /////////////////////////////////////////////////////////////////
1689 //                                               1688 //
1690 //                                               1689 //
1691                                                  1690 
1692  G4complex G4NuclNuclDiffuseElastic::Amplitud    1691  G4complex G4NuclNuclDiffuseElastic::AmplitudeGG(G4double theta)
1693 {                                                1692 {
1694   G4int n;                                       1693   G4int n;
1695   G4double T12b, a, aTemp, b2, sinThetaH = st    1694   G4double T12b, a, aTemp, b2, sinThetaH = std::sin(0.5*theta);
1696   G4double sinThetaH2 = sinThetaH*sinThetaH;     1695   G4double sinThetaH2 = sinThetaH*sinThetaH;
1697   G4complex out = G4complex(0.,0.);              1696   G4complex out = G4complex(0.,0.); 
1698   G4complex im  = G4complex(0.,1.);              1697   G4complex im  = G4complex(0.,1.);
1699                                                  1698 
1700   a  = -fSumSigma/CLHEP::twopi/fNuclearRadius    1699   a  = -fSumSigma/CLHEP::twopi/fNuclearRadiusSquare;
1701   b2 = fWaveVector*fWaveVector*fNuclearRadius    1700   b2 = fWaveVector*fWaveVector*fNuclearRadiusSquare*sinThetaH2;
1702                                                  1701 
1703   aTemp = a;                                     1702   aTemp = a;
1704                                                  1703 
1705   for( n = 1; n < fMaxL; n++)                    1704   for( n = 1; n < fMaxL; n++)
1706   {                                              1705   {    
1707     T12b   = aTemp*G4Exp(-b2/n)/n;               1706     T12b   = aTemp*G4Exp(-b2/n)/n;         
1708     aTemp *= a;                                  1707     aTemp *= a;  
1709     out   += T12b;                               1708     out   += T12b; 
1710     G4cout<<"out = "<<out<<G4endl;               1709     G4cout<<"out = "<<out<<G4endl;  
1711   }                                              1710   }
1712   out *= -4.*im*fWaveVector/CLHEP::pi;           1711   out *= -4.*im*fWaveVector/CLHEP::pi;
1713   out += CoulombAmplitude(theta);                1712   out += CoulombAmplitude(theta);
1714   return out;                                    1713   return out;
1715 }                                                1714 }
1716                                                  1715 
1717                                                  1716 
1718 /////////////////////////////////////////////    1717 ///////////////////////////////////////////////////////////////////////////////
1719 //                                               1718 //
1720 // Test for given particle and element table     1719 // Test for given particle and element table of momentum, angle probability.
1721 // For the partMom in CMS.                       1720 // For the partMom in CMS. 
1722                                                  1721 
1723 void G4NuclNuclDiffuseElastic::InitParameters    1722 void G4NuclNuclDiffuseElastic::InitParameters(const G4ParticleDefinition* theParticle,  
1724                                           G4d    1723                                           G4double partMom, G4double Z, G4double A) 
1725 {                                                1724 {
1726   fAtomicNumber  = Z;     // atomic number       1725   fAtomicNumber  = Z;     // atomic number
1727   fAtomicWeight  = A;     // number of nucleo    1726   fAtomicWeight  = A;     // number of nucleons
1728                                                  1727 
1729   fNuclearRadius2 = CalculateNuclearRad(fAtom    1728   fNuclearRadius2 = CalculateNuclearRad(fAtomicWeight);
1730   G4double A1     = G4double( theParticle->Ge    1729   G4double A1     = G4double( theParticle->GetBaryonNumber() );   
1731   fNuclearRadius1 = CalculateNuclearRad(A1);     1730   fNuclearRadius1 = CalculateNuclearRad(A1);
1732   // fNuclearRadius = std::sqrt(fNuclearRadiu    1731   // fNuclearRadius = std::sqrt(fNuclearRadius1*fNuclearRadius1+fNuclearRadius2*fNuclearRadius2);
1733   fNuclearRadius = fNuclearRadius1 + fNuclear    1732   fNuclearRadius = fNuclearRadius1 + fNuclearRadius2;
1734                                                  1733 
1735   G4double a = 0.;                               1734   G4double a = 0.;
1736   G4double z = theParticle->GetPDGCharge();      1735   G4double z = theParticle->GetPDGCharge();
1737   G4double m1 = theParticle->GetPDGMass();       1736   G4double m1 = theParticle->GetPDGMass();
1738                                                  1737 
1739   fWaveVector = partMom/CLHEP::hbarc;            1738   fWaveVector = partMom/CLHEP::hbarc;
1740                                                  1739 
1741   G4double lambda = fCofLambda*fWaveVector*fN    1740   G4double lambda = fCofLambda*fWaveVector*fNuclearRadius;
1742   G4cout<<"kR = "<<lambda<<G4endl;               1741   G4cout<<"kR = "<<lambda<<G4endl;
1743                                                  1742 
1744   if( z )                                        1743   if( z )
1745   {                                              1744   {
1746     a           = partMom/m1; // beta*gamma f    1745     a           = partMom/m1; // beta*gamma for m1
1747     fBeta       = a/std::sqrt(1+a*a);            1746     fBeta       = a/std::sqrt(1+a*a);
1748     fZommerfeld = CalculateZommerfeld( fBeta,    1747     fZommerfeld = CalculateZommerfeld( fBeta, z, fAtomicNumber);
1749     fRutherfordRatio = fZommerfeld/fWaveVecto    1748     fRutherfordRatio = fZommerfeld/fWaveVector; 
1750     fAm         = CalculateAm( partMom, fZomm    1749     fAm         = CalculateAm( partMom, fZommerfeld, fAtomicNumber);
1751   }                                              1750   }
1752   G4cout<<"fZommerfeld = "<<fZommerfeld<<G4en    1751   G4cout<<"fZommerfeld = "<<fZommerfeld<<G4endl;
1753   fProfileLambda = lambda; // *std::sqrt(1.-2    1752   fProfileLambda = lambda; // *std::sqrt(1.-2*fZommerfeld/lambda);
1754   G4cout<<"fProfileLambda = "<<fProfileLambda    1753   G4cout<<"fProfileLambda = "<<fProfileLambda<<G4endl;
1755   fProfileDelta  = fCofDelta*fProfileLambda;     1754   fProfileDelta  = fCofDelta*fProfileLambda;
1756   fProfileAlpha  = fCofAlpha*fProfileLambda;     1755   fProfileAlpha  = fCofAlpha*fProfileLambda;
1757                                                  1756 
1758   CalculateCoulombPhaseZero();                   1757   CalculateCoulombPhaseZero();
1759   CalculateRutherfordAnglePar();                 1758   CalculateRutherfordAnglePar();
1760                                                  1759 
1761   return;                                        1760   return;
1762 }                                                1761 }
1763 /////////////////////////////////////////////    1762 ///////////////////////////////////////////////////////////////////////////////
1764 //                                               1763 //
1765 // Test for given particle and element table     1764 // Test for given particle and element table of momentum, angle probability.
1766 // For the partMom in CMS.                       1765 // For the partMom in CMS. 
1767                                                  1766 
1768 void G4NuclNuclDiffuseElastic::InitDynParamet    1767 void G4NuclNuclDiffuseElastic::InitDynParameters(const G4ParticleDefinition* theParticle,  
1769                                           G4d    1768                                           G4double partMom) 
1770 {                                                1769 {
1771   G4double a = 0.;                               1770   G4double a = 0.;
1772   G4double z = theParticle->GetPDGCharge();      1771   G4double z = theParticle->GetPDGCharge();
1773   G4double m1 = theParticle->GetPDGMass();       1772   G4double m1 = theParticle->GetPDGMass();
1774                                                  1773 
1775   fWaveVector = partMom/CLHEP::hbarc;            1774   fWaveVector = partMom/CLHEP::hbarc;
1776                                                  1775 
1777   G4double lambda = fCofLambda*fWaveVector*fN    1776   G4double lambda = fCofLambda*fWaveVector*fNuclearRadius;
1778                                                  1777 
1779   if( z )                                        1778   if( z )
1780   {                                              1779   {
1781     a           = partMom/m1; // beta*gamma f    1780     a           = partMom/m1; // beta*gamma for m1
1782     fBeta       = a/std::sqrt(1+a*a);            1781     fBeta       = a/std::sqrt(1+a*a);
1783     fZommerfeld = CalculateZommerfeld( fBeta,    1782     fZommerfeld = CalculateZommerfeld( fBeta, z, fAtomicNumber);
1784     fRutherfordRatio = fZommerfeld/fWaveVecto    1783     fRutherfordRatio = fZommerfeld/fWaveVector; 
1785     fAm         = CalculateAm( partMom, fZomm    1784     fAm         = CalculateAm( partMom, fZommerfeld, fAtomicNumber);
1786   }                                              1785   }
1787   fProfileLambda = lambda; // *std::sqrt(1.-2    1786   fProfileLambda = lambda; // *std::sqrt(1.-2*fZommerfeld/lambda);
1788   fProfileDelta  = fCofDelta*fProfileLambda;     1787   fProfileDelta  = fCofDelta*fProfileLambda;
1789   fProfileAlpha  = fCofAlpha*fProfileLambda;     1788   fProfileAlpha  = fCofAlpha*fProfileLambda;
1790                                                  1789 
1791   CalculateCoulombPhaseZero();                   1790   CalculateCoulombPhaseZero();
1792   CalculateRutherfordAnglePar();                 1791   CalculateRutherfordAnglePar();
1793                                                  1792 
1794   return;                                        1793   return;
1795 }                                                1794 }
1796                                                  1795 
1797                                                  1796 
1798 /////////////////////////////////////////////    1797 ///////////////////////////////////////////////////////////////////////////////
1799 //                                               1798 //
1800 // Test for given particle and element table     1799 // Test for given particle and element table of momentum, angle probability.
1801 // For the partMom in CMS.                       1800 // For the partMom in CMS. 
1802                                                  1801 
1803 void G4NuclNuclDiffuseElastic::InitParameters    1802 void G4NuclNuclDiffuseElastic::InitParametersGla(const G4DynamicParticle* aParticle,  
1804                                           G4d    1803                                           G4double partMom, G4double Z, G4double A) 
1805 {                                                1804 {
1806   fAtomicNumber  = Z;     // target atomic nu    1805   fAtomicNumber  = Z;     // target atomic number
1807   fAtomicWeight  = A;     // target number of    1806   fAtomicWeight  = A;     // target number of nucleons
1808                                                  1807 
1809   fNuclearRadius2 = CalculateNuclearRad(fAtom    1808   fNuclearRadius2 = CalculateNuclearRad(fAtomicWeight); // target nucleus radius
1810   G4double A1     = G4double( aParticle->GetD    1809   G4double A1     = G4double( aParticle->GetDefinition()->GetBaryonNumber() );   
1811   fNuclearRadius1 = CalculateNuclearRad(A1);     1810   fNuclearRadius1 = CalculateNuclearRad(A1); // projectile nucleus radius
1812   fNuclearRadiusSquare = fNuclearRadius1*fNuc    1811   fNuclearRadiusSquare = fNuclearRadius1*fNuclearRadius1+fNuclearRadius2*fNuclearRadius2;
1813                                                  1812  
1814                                                  1813 
1815   G4double a  = 0., kR12;                        1814   G4double a  = 0., kR12;
1816   G4double z  = aParticle->GetDefinition()->G    1815   G4double z  = aParticle->GetDefinition()->GetPDGCharge();
1817   G4double m1 = aParticle->GetDefinition()->G    1816   G4double m1 = aParticle->GetDefinition()->GetPDGMass();
1818                                                  1817 
1819   fWaveVector = partMom/CLHEP::hbarc;            1818   fWaveVector = partMom/CLHEP::hbarc;
1820                                                  1819 
1821   G4double pN = A1 - z;                          1820   G4double pN = A1 - z;
1822   if( pN < 0. ) pN = 0.;                         1821   if( pN < 0. ) pN = 0.;
1823                                                  1822 
1824   G4double tN = A - Z;                           1823   G4double tN = A - Z;
1825   if( tN < 0. ) tN = 0.;                         1824   if( tN < 0. ) tN = 0.;
1826                                                  1825 
1827   G4double pTkin = aParticle->GetKineticEnerg    1826   G4double pTkin = aParticle->GetKineticEnergy();  
1828   pTkin /= A1;                                   1827   pTkin /= A1;
1829                                                  1828 
1830                                                  1829 
1831   fSumSigma = (Z*z+pN*tN)*GetHadronNucleonXsc    1830   fSumSigma = (Z*z+pN*tN)*GetHadronNucleonXscNS(theProton, pTkin, theProton) +
1832               (z*tN+pN*Z)*GetHadronNucleonXsc    1831               (z*tN+pN*Z)*GetHadronNucleonXscNS(theProton, pTkin, theNeutron);
1833                                                  1832 
1834   G4cout<<"fSumSigma = "<<fSumSigma/CLHEP::mi    1833   G4cout<<"fSumSigma = "<<fSumSigma/CLHEP::millibarn<<" mb"<<G4endl;
1835   G4cout<<"pi*R2 = "<<CLHEP::pi*fNuclearRadiu    1834   G4cout<<"pi*R2 = "<<CLHEP::pi*fNuclearRadiusSquare/CLHEP::millibarn<<" mb"<<G4endl;
1836   kR12 = fWaveVector*std::sqrt(fNuclearRadius    1835   kR12 = fWaveVector*std::sqrt(fNuclearRadiusSquare);
1837   G4cout<<"k*sqrt(R2) = "<<kR12<<" "<<G4endl;    1836   G4cout<<"k*sqrt(R2) = "<<kR12<<" "<<G4endl;
1838   fMaxL = (G4int(kR12)+1)*4;                     1837   fMaxL = (G4int(kR12)+1)*4;
1839   G4cout<<"fMaxL = "<<fMaxL<<" "<<G4endl;        1838   G4cout<<"fMaxL = "<<fMaxL<<" "<<G4endl;
1840                                                  1839 
1841   if( z )                                        1840   if( z )
1842   {                                              1841   {
1843       a           = partMom/m1; // beta*gamma    1842       a           = partMom/m1; // beta*gamma for m1
1844       fBeta       = a/std::sqrt(1+a*a);          1843       fBeta       = a/std::sqrt(1+a*a);
1845       fZommerfeld = CalculateZommerfeld( fBet    1844       fZommerfeld = CalculateZommerfeld( fBeta, z, fAtomicNumber);
1846       fAm         = CalculateAm( partMom, fZo    1845       fAm         = CalculateAm( partMom, fZommerfeld, fAtomicNumber);
1847   }                                              1846   }
1848                                                  1847 
1849   CalculateCoulombPhaseZero();                   1848   CalculateCoulombPhaseZero();
1850                                                  1849  
1851                                                  1850 
1852   return;                                        1851   return;
1853 }                                                1852 }
1854                                                  1853 
1855                                                  1854 
1856 /////////////////////////////////////////////    1855 /////////////////////////////////////////////////////////////////////////////////////
1857 //                                               1856 //
1858 // Returns nucleon-nucleon cross-section base    1857 // Returns nucleon-nucleon cross-section based on N. Starkov parametrisation of
1859 // data from mainly http://wwwppds.ihep.su:80    1858 // data from mainly http://wwwppds.ihep.su:8001/c5-6A.html database
1860 // projectile nucleon is pParticle with pTkin    1859 // projectile nucleon is pParticle with pTkin shooting target nucleon tParticle
1861                                                  1860 
1862 G4double                                         1861 G4double 
1863 G4NuclNuclDiffuseElastic::GetHadronNucleonXsc    1862 G4NuclNuclDiffuseElastic::GetHadronNucleonXscNS( G4ParticleDefinition* pParticle, 
1864                                                  1863                                                  G4double pTkin, 
1865                                                  1864                                                  G4ParticleDefinition* tParticle)
1866 {                                                1865 {
1867   G4double xsection(0), /*Delta,*/ A0, B0;       1866   G4double xsection(0), /*Delta,*/ A0, B0;
1868   G4double hpXsc(0);                             1867   G4double hpXsc(0);
1869   G4double hnXsc(0);                             1868   G4double hnXsc(0);
1870                                                  1869 
1871                                                  1870 
1872   G4double targ_mass     = tParticle->GetPDGM    1871   G4double targ_mass     = tParticle->GetPDGMass();
1873   G4double proj_mass     = pParticle->GetPDGM    1872   G4double proj_mass     = pParticle->GetPDGMass(); 
1874                                                  1873 
1875   G4double proj_energy   = proj_mass + pTkin;    1874   G4double proj_energy   = proj_mass + pTkin; 
1876   G4double proj_momentum = std::sqrt(pTkin*(p    1875   G4double proj_momentum = std::sqrt(pTkin*(pTkin+2*proj_mass));
1877                                                  1876 
1878   G4double sMand = CalcMandelstamS ( proj_mas    1877   G4double sMand = CalcMandelstamS ( proj_mass , targ_mass , proj_momentum );
1879                                                  1878 
1880   sMand         /= CLHEP::GeV*CLHEP::GeV;  //    1879   sMand         /= CLHEP::GeV*CLHEP::GeV;  // in GeV for parametrisation
1881   proj_momentum /= CLHEP::GeV;                   1880   proj_momentum /= CLHEP::GeV;
1882   proj_energy   /= CLHEP::GeV;                   1881   proj_energy   /= CLHEP::GeV;
1883   proj_mass     /= CLHEP::GeV;                   1882   proj_mass     /= CLHEP::GeV;
1884   G4double logS = G4Log(sMand);                  1883   G4double logS = G4Log(sMand);
1885                                                  1884 
1886   // General PDG fit constants                   1885   // General PDG fit constants
1887                                                  1886 
1888                                                  1887 
1889   // fEtaRatio=Re[f(0)]/Im[f(0)]                 1888   // fEtaRatio=Re[f(0)]/Im[f(0)]
1890                                                  1889 
1891   if( proj_momentum >= 1.2 )                     1890   if( proj_momentum >= 1.2 )
1892   {                                              1891   {
1893     fEtaRatio  = 0.13*(logS - 5.8579332)*G4Po    1892     fEtaRatio  = 0.13*(logS - 5.8579332)*G4Pow::GetInstance()->powA(sMand,-0.18);
1894   }                                              1893   }       
1895   else if( proj_momentum >= 0.6 )                1894   else if( proj_momentum >= 0.6 )
1896   {                                              1895   { 
1897     fEtaRatio = -75.5*(G4Pow::GetInstance()->    1896     fEtaRatio = -75.5*(G4Pow::GetInstance()->powA(proj_momentum,0.25)-0.95)/
1898     (G4Pow::GetInstance()->powA(3*proj_moment    1897     (G4Pow::GetInstance()->powA(3*proj_momentum,2.2)+1);     
1899   }                                              1898   }
1900   else                                           1899   else 
1901   {                                              1900   {
1902     fEtaRatio = 15.5*proj_momentum/(27*proj_m    1901     fEtaRatio = 15.5*proj_momentum/(27*proj_momentum*proj_momentum*proj_momentum+2);
1903   }                                              1902   }
1904   G4cout<<"fEtaRatio = "<<fEtaRatio<<G4endl;     1903   G4cout<<"fEtaRatio = "<<fEtaRatio<<G4endl;
1905                                                  1904 
1906   // xsc                                         1905   // xsc
1907                                                  1906   
1908   if( proj_momentum >= 10. ) // high energy:     1907   if( proj_momentum >= 10. ) // high energy: pp = nn = np
1909     // if( proj_momentum >= 2.)                  1908     // if( proj_momentum >= 2.)
1910   {                                              1909   {
1911     //Delta = 1.;                                1910     //Delta = 1.;
1912                                                  1911 
1913     //if( proj_energy < 40. ) Delta = 0.916+0    1912     //if( proj_energy < 40. ) Delta = 0.916+0.0021*proj_energy;
1914                                                  1913 
1915     //AR-12Aug2016  if( proj_momentum >= 10.)    1914     //AR-12Aug2016  if( proj_momentum >= 10.)
1916     {                                            1915     {
1917         B0 = 7.5;                                1916         B0 = 7.5;
1918         A0 = 100. - B0*G4Log(3.0e7);             1917         A0 = 100. - B0*G4Log(3.0e7);
1919                                                  1918 
1920         xsection = A0 + B0*G4Log(proj_energy)    1919         xsection = A0 + B0*G4Log(proj_energy) - 11
1921                   + 103*G4Pow::GetInstance()-    1920                   + 103*G4Pow::GetInstance()->powA(2*0.93827*proj_energy + proj_mass*proj_mass+
1922                      0.93827*0.93827,-0.165);    1921                      0.93827*0.93827,-0.165);        //  mb
1923     }                                            1922     }
1924   }                                              1923   }
1925   else // low energy pp = nn != np               1924   else // low energy pp = nn != np
1926   {                                              1925   {
1927       if(pParticle == tParticle) // pp or nn     1926       if(pParticle == tParticle) // pp or nn      // nn to be pp
1928       {                                          1927       {
1929         if( proj_momentum < 0.73 )               1928         if( proj_momentum < 0.73 )
1930         {                                        1929         {
1931           hnXsc = 23 + 50*( G4Pow::GetInstanc    1930           hnXsc = 23 + 50*( G4Pow::GetInstance()->powA( G4Log(0.73/proj_momentum), 3.5 ) );
1932         }                                        1931         }
1933         else if( proj_momentum < 1.05  )         1932         else if( proj_momentum < 1.05  )
1934         {                                        1933         {
1935           hnXsc = 23 + 40*(G4Log(proj_momentu    1934           hnXsc = 23 + 40*(G4Log(proj_momentum/0.73))*
1936                          (G4Log(proj_momentum    1935                          (G4Log(proj_momentum/0.73));
1937         }                                        1936         }
1938         else  // if( proj_momentum < 10.  )      1937         else  // if( proj_momentum < 10.  )
1939         {                                        1938         {
1940           hnXsc = 39.0 +                         1939           hnXsc = 39.0 + 
1941               75*(proj_momentum - 1.2)/(G4Pow    1940               75*(proj_momentum - 1.2)/(G4Pow::GetInstance()->powA(proj_momentum,3.0) + 0.15);
1942         }                                        1941         }
1943         xsection = hnXsc;                        1942         xsection = hnXsc;
1944       }                                          1943       }
1945       else  // pn to be np                       1944       else  // pn to be np
1946       {                                          1945       {
1947         if( proj_momentum < 0.8 )                1946         if( proj_momentum < 0.8 )
1948         {                                        1947         {
1949           hpXsc = 33+30*G4Pow::GetInstance()-    1948           hpXsc = 33+30*G4Pow::GetInstance()->powA(G4Log(proj_momentum/1.3),4.0);
1950         }                                        1949         }      
1951         else if( proj_momentum < 1.4 )           1950         else if( proj_momentum < 1.4 )
1952         {                                        1951         {
1953           hpXsc = 33+30*G4Pow::GetInstance()-    1952           hpXsc = 33+30*G4Pow::GetInstance()->powA(G4Log(proj_momentum/0.95),2.0);
1954         }                                        1953         }
1955         else    // if( proj_momentum < 10.  )    1954         else    // if( proj_momentum < 10.  )
1956         {                                        1955         {
1957           hpXsc = 33.3+                          1956           hpXsc = 33.3+
1958               20.8*(G4Pow::GetInstance()->pow    1957               20.8*(G4Pow::GetInstance()->powA(proj_momentum,2.0)-1.35)/
1959                  (G4Pow::GetInstance()->powA(    1958                  (G4Pow::GetInstance()->powA(proj_momentum,2.50)+0.95);
1960         }                                        1959         }
1961         xsection = hpXsc;                        1960         xsection = hpXsc;
1962       }                                          1961       }
1963   }                                              1962   }
1964   xsection *= CLHEP::millibarn; // parametris    1963   xsection *= CLHEP::millibarn; // parametrised in mb
1965   G4cout<<"xsection = "<<xsection/CLHEP::mill    1964   G4cout<<"xsection = "<<xsection/CLHEP::millibarn<<" mb"<<G4endl;
1966   return xsection;                               1965   return xsection;
1967 }                                                1966 }
1968                                                  1967 
1969 /////////////////////////////////////////////    1968 /////////////////////////////////////////////////////////////////
1970 //                                               1969 //
1971 // The ratio el/ruth for Fresnel smooth nucle    1970 // The ratio el/ruth for Fresnel smooth nucleus profile
1972                                                  1971 
1973 G4double G4NuclNuclDiffuseElastic::GetRatioGe    1972 G4double G4NuclNuclDiffuseElastic::GetRatioGen(G4double theta)
1974 {                                                1973 {
1975   G4double sinThetaR  = 2.*fHalfRutThetaTg/(1    1974   G4double sinThetaR  = 2.*fHalfRutThetaTg/(1. + fHalfRutThetaTg2);
1976   G4double dTheta     = 0.5*(theta - fRutherf    1975   G4double dTheta     = 0.5*(theta - fRutherfordTheta);
1977   G4double sindTheta  = std::sin(dTheta);        1976   G4double sindTheta  = std::sin(dTheta);
1978                                                  1977 
1979   G4double prof       = Profile(theta);          1978   G4double prof       = Profile(theta);
1980   G4double prof2      = prof*prof;               1979   G4double prof2      = prof*prof;
1981   // G4double profmod    = std::abs(prof);       1980   // G4double profmod    = std::abs(prof);
1982   G4double order      = std::sqrt(fProfileLam    1981   G4double order      = std::sqrt(fProfileLambda/sinThetaR/CLHEP::pi)*2.*sindTheta;
1983                                                  1982 
1984   order = std::abs(order); // since sin chang    1983   order = std::abs(order); // since sin changes sign!
1985   // G4cout<<"order = "<<order<<G4endl;          1984   // G4cout<<"order = "<<order<<G4endl; 
1986                                                  1985  
1987   G4double cosFresnel = GetCint(order);          1986   G4double cosFresnel = GetCint(order);  
1988   G4double sinFresnel = GetSint(order);          1987   G4double sinFresnel = GetSint(order);  
1989                                                  1988 
1990   G4double out;                                  1989   G4double out;
1991                                                  1990 
1992   if ( theta <= fRutherfordTheta )               1991   if ( theta <= fRutherfordTheta )
1993   {                                              1992   {
1994     out  = 1. + 0.5*( (0.5-cosFresnel)*(0.5-c    1993     out  = 1. + 0.5*( (0.5-cosFresnel)*(0.5-cosFresnel)+(0.5-sinFresnel)*(0.5-sinFresnel) )*prof2; 
1995     out += ( cosFresnel + sinFresnel - 1. )*p    1994     out += ( cosFresnel + sinFresnel - 1. )*prof;
1996   }                                              1995   }
1997   else                                           1996   else
1998   {                                              1997   {
1999     out = 0.5*( (0.5-cosFresnel)*(0.5-cosFres    1998     out = 0.5*( (0.5-cosFresnel)*(0.5-cosFresnel)+(0.5-sinFresnel)*(0.5-sinFresnel) )*prof2;
2000   }                                              1999   }
2001                                                  2000 
2002   return out;                                    2001   return out;
2003 }                                                2002 }
2004                                                  2003 
2005 /////////////////////////////////////////////    2004 ///////////////////////////////////////////////////////////////////
2006 //                                               2005 //
2007 // For the calculation of arg Gamma(z) one ne    2006 // For the calculation of arg Gamma(z) one needs complex extension 
2008 // of ln(Gamma(z))                               2007 // of ln(Gamma(z))
2009                                                  2008 
2010 G4complex G4NuclNuclDiffuseElastic::GammaLoga    2009 G4complex G4NuclNuclDiffuseElastic::GammaLogarithm(G4complex zz)
2011 {                                                2010 {
2012   const G4double cof[6] = { 76.18009172947146    2011   const G4double cof[6] = { 76.18009172947146,     -86.50532032941677,
2013                              24.0140982408309    2012                              24.01409824083091,      -1.231739572450155,
2014                               0.1208650973866    2013                               0.1208650973866179e-2, -0.5395239384953e-5  } ;
2015   G4int j;                                       2014   G4int j;
2016   G4complex z = zz - 1.0;                        2015   G4complex z = zz - 1.0;
2017   G4complex tmp = z + 5.5;                       2016   G4complex tmp = z + 5.5;
2018   tmp -= (z + 0.5) * std::log(tmp);              2017   tmp -= (z + 0.5) * std::log(tmp);
2019   G4complex ser = G4complex(1.000000000190015    2018   G4complex ser = G4complex(1.000000000190015,0.);
2020                                                  2019 
2021   for ( j = 0; j <= 5; j++ )                     2020   for ( j = 0; j <= 5; j++ )
2022   {                                              2021   {
2023     z += 1.0;                                    2022     z += 1.0;
2024     ser += cof[j]/z;                             2023     ser += cof[j]/z;
2025   }                                              2024   }
2026   return -tmp + std::log(2.5066282746310005*s    2025   return -tmp + std::log(2.5066282746310005*ser);
2027 }                                                2026 }
2028                                                  2027 
2029 /////////////////////////////////////////////    2028 /////////////////////////////////////////////////////////////
2030 //                                               2029 //
2031 // Bessel J0 function based on rational appro    2030 // Bessel J0 function based on rational approximation from 
2032 // J.F. Hart, Computer Approximations, New Yo    2031 // J.F. Hart, Computer Approximations, New York, Willey 1968, p. 141 
2033                                                  2032 
2034 G4double G4NuclNuclDiffuseElastic::BesselJzer    2033 G4double G4NuclNuclDiffuseElastic::BesselJzero(G4double value)
2035 {                                                2034 {
2036   G4double modvalue, value2, fact1, fact2, ar    2035   G4double modvalue, value2, fact1, fact2, arg, shift, bessel;
2037                                                  2036 
2038   modvalue = std::fabs(value);                   2037   modvalue = std::fabs(value);
2039                                                  2038 
2040   if ( value < 8.0 && value > -8.0 )             2039   if ( value < 8.0 && value > -8.0 )
2041   {                                              2040   {
2042     value2 = value*value;                        2041     value2 = value*value;
2043                                                  2042 
2044     fact1  = 57568490574.0 + value2*(-1336259    2043     fact1  = 57568490574.0 + value2*(-13362590354.0 
2045                            + value2*( 6516196    2044                            + value2*( 651619640.7 
2046                            + value2*(-1121442    2045                            + value2*(-11214424.18 
2047                            + value2*( 77392.3    2046                            + value2*( 77392.33017 
2048                            + value2*(-184.905    2047                            + value2*(-184.9052456   ) ) ) ) );
2049                                                  2048 
2050     fact2  = 57568490411.0 + value2*( 1029532    2049     fact2  = 57568490411.0 + value2*( 1029532985.0 
2051                            + value2*( 9494680    2050                            + value2*( 9494680.718
2052                            + value2*(59272.64    2051                            + value2*(59272.64853
2053                            + value2*(267.8532    2052                            + value2*(267.8532712 
2054                            + value2*1.0          2053                            + value2*1.0               ) ) ) );
2055                                                  2054 
2056     bessel = fact1/fact2;                        2055     bessel = fact1/fact2;
2057   }                                              2056   } 
2058   else                                           2057   else 
2059   {                                              2058   {
2060     arg    = 8.0/modvalue;                       2059     arg    = 8.0/modvalue;
2061                                                  2060 
2062     value2 = arg*arg;                            2061     value2 = arg*arg;
2063                                                  2062 
2064     shift  = modvalue-0.785398164;               2063     shift  = modvalue-0.785398164;
2065                                                  2064 
2066     fact1  = 1.0 + value2*(-0.1098628627e-2      2065     fact1  = 1.0 + value2*(-0.1098628627e-2 
2067                  + value2*(0.2734510407e-4       2066                  + value2*(0.2734510407e-4
2068                  + value2*(-0.2073370639e-5      2067                  + value2*(-0.2073370639e-5 
2069                  + value2*0.2093887211e-6        2068                  + value2*0.2093887211e-6    ) ) );
2070                                                  2069 
2071     fact2  = -0.1562499995e-1 + value2*(0.143    2070     fact2  = -0.1562499995e-1 + value2*(0.1430488765e-3
2072                               + value2*(-0.69    2071                               + value2*(-0.6911147651e-5 
2073                               + value2*(0.762    2072                               + value2*(0.7621095161e-6
2074                               - value2*0.9349    2073                               - value2*0.934945152e-7    ) ) );
2075                                                  2074 
2076     bessel = std::sqrt(0.636619772/modvalue)*    2075     bessel = std::sqrt(0.636619772/modvalue)*(std::cos(shift)*fact1 - arg*std::sin(shift)*fact2 );
2077   }                                              2076   }
2078   return bessel;                                 2077   return bessel;
2079 }                                                2078 }
2080                                                  2079 
2081 /////////////////////////////////////////////    2080 /////////////////////////////////////////////////////////////
2082 //                                               2081 //
2083 // Bessel J1 function based on rational appro    2082 // Bessel J1 function based on rational approximation from 
2084 // J.F. Hart, Computer Approximations, New Yo    2083 // J.F. Hart, Computer Approximations, New York, Willey 1968, p. 141 
2085                                                  2084 
2086 G4double G4NuclNuclDiffuseElastic::BesselJone    2085 G4double G4NuclNuclDiffuseElastic::BesselJone(G4double value)
2087 {                                                2086 {
2088   G4double modvalue, value2, fact1, fact2, ar    2087   G4double modvalue, value2, fact1, fact2, arg, shift, bessel;
2089                                                  2088 
2090   modvalue = std::fabs(value);                   2089   modvalue = std::fabs(value);
2091                                                  2090 
2092   if ( modvalue < 8.0 )                          2091   if ( modvalue < 8.0 ) 
2093   {                                              2092   {
2094     value2 = value*value;                        2093     value2 = value*value;
2095                                                  2094 
2096     fact1  = value*(72362614232.0 + value2*(-    2095     fact1  = value*(72362614232.0 + value2*(-7895059235.0 
2097                                   + value2*(     2096                                   + value2*( 242396853.1
2098                                   + value2*(-    2097                                   + value2*(-2972611.439 
2099                                   + value2*(     2098                                   + value2*( 15704.48260 
2100                                   + value2*(-    2099                                   + value2*(-30.16036606  ) ) ) ) ) );
2101                                                  2100 
2102     fact2  = 144725228442.0 + value2*(2300535    2101     fact2  = 144725228442.0 + value2*(2300535178.0 
2103                             + value2*(1858330    2102                             + value2*(18583304.74
2104                             + value2*(99447.4    2103                             + value2*(99447.43394 
2105                             + value2*(376.999    2104                             + value2*(376.9991397 
2106                             + value2*1.0         2105                             + value2*1.0             ) ) ) );
2107     bessel = fact1/fact2;                        2106     bessel = fact1/fact2;
2108   }                                              2107   } 
2109   else                                           2108   else 
2110   {                                              2109   {
2111     arg    = 8.0/modvalue;                       2110     arg    = 8.0/modvalue;
2112                                                  2111 
2113     value2 = arg*arg;                            2112     value2 = arg*arg;
2114                                                  2113 
2115     shift  = modvalue - 2.356194491;             2114     shift  = modvalue - 2.356194491;
2116                                                  2115 
2117     fact1  = 1.0 + value2*( 0.183105e-2          2116     fact1  = 1.0 + value2*( 0.183105e-2 
2118                  + value2*(-0.3516396496e-4      2117                  + value2*(-0.3516396496e-4
2119                  + value2*(0.2457520174e-5       2118                  + value2*(0.2457520174e-5 
2120                  + value2*(-0.240337019e-6       2119                  + value2*(-0.240337019e-6          ) ) ) );
2121                                                  2120 
2122     fact2 = 0.04687499995 + value2*(-0.200269    2121     fact2 = 0.04687499995 + value2*(-0.2002690873e-3
2123                           + value2*( 0.844919    2122                           + value2*( 0.8449199096e-5
2124                           + value2*(-0.882289    2123                           + value2*(-0.88228987e-6
2125                           + value2*0.10578741    2124                           + value2*0.105787412e-6       ) ) );
2126                                                  2125 
2127     bessel = std::sqrt( 0.636619772/modvalue)    2126     bessel = std::sqrt( 0.636619772/modvalue)*(std::cos(shift)*fact1 - arg*std::sin(shift)*fact2);
2128                                                  2127 
2129     if (value < 0.0) bessel = -bessel;           2128     if (value < 0.0) bessel = -bessel;
2130   }                                              2129   }
2131   return bessel;                                 2130   return bessel;
2132 }                                                2131 }
2133                                                  2132 
2134 //                                               2133 //
2135 //                                               2134 //
2136 /////////////////////////////////////////////    2135 /////////////////////////////////////////////////////////////////////////////////
2137                                                  2136