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Geant4/processes/hadronic/models/de_excitation/multifragmentation/src/G4StatMFChannel.cc

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Diff markup

Differences between /processes/hadronic/models/de_excitation/multifragmentation/src/G4StatMFChannel.cc (Version 11.3.0) and /processes/hadronic/models/de_excitation/multifragmentation/src/G4StatMFChannel.cc (Version 5.2)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25 //                                                
 26 //                                                
 27 //                                                
 28 // Hadronic Process: Nuclear De-excitations       
 29 // by V. Lara                                     
 30 //                                                
 31 // Modified:                                      
 32 // 25.07.08 I.Pshenichnov (in collaboration wi    
 33 //          Mishustin (FIAS, Frankfurt, INR, M    
 34 //          Moscow, pshenich@fias.uni-frankfur    
 35                                                   
 36 #include <numeric>                                
 37                                                   
 38 #include "G4StatMFChannel.hh"                     
 39 #include "G4PhysicalConstants.hh"                 
 40 #include "G4HadronicException.hh"                 
 41 #include "Randomize.hh"                           
 42 #include "G4Pow.hh"                               
 43 #include "G4Exp.hh"                               
 44 #include "G4RandomDirection.hh"                   
 45                                                   
 46 G4StatMFChannel::G4StatMFChannel() :              
 47   _NumOfNeutralFragments(0),                      
 48   _NumOfChargedFragments(0)                       
 49 {                                                 
 50   Pos.resize(8);                                  
 51   Vel.resize(8);                                  
 52   Accel.resize(8);                                
 53 }                                                 
 54                                                   
 55 G4StatMFChannel::~G4StatMFChannel()               
 56 {                                                 
 57   if (!_theFragments.empty()) {                   
 58     std::for_each(_theFragments.begin(),_theFr    
 59       DeleteFragment());                          
 60   }                                               
 61 }                                                 
 62                                                   
 63 G4bool G4StatMFChannel::CheckFragments(void)      
 64 {                                                 
 65   std::deque<G4StatMFFragment*>::iterator i;      
 66   for (i = _theFragments.begin();                 
 67        i != _theFragments.end(); ++i)             
 68     {                                             
 69       G4int A = (*i)->GetA();                     
 70       G4int Z = (*i)->GetZ();                     
 71       if ( (A > 1 && (Z > A || Z <= 0)) || (A=    
 72     }                                             
 73     return true;                                  
 74 }                                                 
 75                                                   
 76 void G4StatMFChannel::CreateFragment(G4int A,     
 77 // Create a new fragment.                         
 78 // Fragments are automatically sorted: first c    
 79 // then neutral ones.                             
 80 {                                                 
 81   if (Z <= 0.5) {                                 
 82     _theFragments.push_back(new G4StatMFFragme    
 83     _NumOfNeutralFragments++;                     
 84   } else {                                        
 85     _theFragments.push_front(new G4StatMFFragm    
 86     _NumOfChargedFragments++;                     
 87   }                                               
 88                                                   
 89   return;                                         
 90 }                                                 
 91                                                   
 92 G4double G4StatMFChannel::GetFragmentsCoulombE    
 93 {                                                 
 94   G4double Coulomb =                              
 95     std::accumulate(_theFragments.begin(),_the    
 96                     0.0,                          
 97                     [](const G4double& running    
 98                        G4StatMFFragment*& frag    
 99                     {                             
100                       return running_total + f    
101                     } );                          
102   //      G4double Coulomb = 0.0;                 
103   //      for (unsigned int i = 0;i < _theFrag    
104   //    Coulomb += _theFragments[i]->GetCoulom    
105   return Coulomb;                                 
106 }                                                 
107                                                   
108 G4double G4StatMFChannel::GetFragmentsEnergy(G    
109 {                                                 
110   G4double Energy = 0.0;                          
111                                                   
112   G4double TranslationalEnergy = 1.5*T*_theFra    
113                                                   
114   std::deque<G4StatMFFragment*>::const_iterato    
115   for (i = _theFragments.begin(); i != _theFra    
116     {                                             
117       Energy += (*i)->GetEnergy(T);               
118     }                                             
119   return Energy + TranslationalEnergy;            
120 }                                                 
121                                                   
122 G4FragmentVector * G4StatMFChannel::GetFragmen    
123              G4int anZ,                           
124              G4double T)                          
125 {                                                 
126   // calculate momenta of charged fragments       
127   CoulombImpulse(anA,anZ,T);                      
128                                                   
129   // calculate momenta of neutral fragments       
130   FragmentsMomenta(_NumOfNeutralFragments, _Nu    
131                                                   
132   G4FragmentVector * theResult = new G4Fragmen    
133   std::deque<G4StatMFFragment*>::iterator i;      
134   for (i = _theFragments.begin(); i != _theFra    
135     theResult->push_back((*i)->GetFragment(T))    
136                                                   
137   return theResult;                               
138 }                                                 
139                                                   
140 void G4StatMFChannel::CoulombImpulse(G4int anA    
141 // Aafter breakup, fragments fly away under Co    
142 // This method calculates asymptotic fragments    
143 {                                                 
144   // First, we have to place the fragments ins    
145   PlaceFragments(anA);                            
146                                                   
147   // Second, we sample initial charged fragmen    
148   // _NumOfChargedFragments charged fragments     
149   // of the vector _theFragments (i.e. 0)         
150   FragmentsMomenta(_NumOfChargedFragments, 0,     
151                                                   
152   // Third, we have to figure out the asymptot    
153   // For taht we have to solve equations of mo    
154   SolveEqOfMotion(anA,anZ,T);                     
155                                                   
156   return;                                         
157 }                                                 
158                                                   
159 void G4StatMFChannel::PlaceFragments(G4int anA    
160 // This gives the position of fragments at the    
161 // Fragments positions are sampled inside prol    
162 {                                                 
163   G4Pow* g4calc = G4Pow::GetInstance();           
164   const G4double R0 = G4StatMFParameters::Getr    
165   G4double Rsys = 2.0*R0*g4calc->Z13(anA);        
166                                                   
167   G4bool TooMuchIterations;                       
168   do                                              
169     {                                             
170       TooMuchIterations = false;                  
171                                                   
172       // Sample the position of the first frag    
173       G4double R = (Rsys - R0*g4calc->Z13(_the    
174   g4calc->A13(G4UniformRand());                   
175       _theFragments[0]->SetPosition(R*G4Random    
176                                                   
177                                                   
178       // Sample the position of the remaining     
179       G4bool ThereAreOverlaps = false;            
180       std::deque<G4StatMFFragment*>::iterator     
181       for (i = _theFragments.begin()+1; i != _    
182   {                                               
183     G4int counter = 0;                            
184     do                                            
185       {                                           
186         R = (Rsys - R0*g4calc->Z13((*i)->GetA(    
187         (*i)->SetPosition(R*G4RandomDirection(    
188                                                   
189         // Check that there are not overlappin    
190         std::deque<G4StatMFFragment*>::iterato    
191         for (j = _theFragments.begin(); j != i    
192     {                                             
193       G4ThreeVector FragToFragVector =            
194         (*i)->GetPosition() - (*j)->GetPositio    
195       G4double Rmin = R0*(g4calc->Z13((*i)->Ge    
196               g4calc->Z13((*j)->GetA()));         
197       if ( (ThereAreOverlaps = (FragToFragVect    
198         { break; }                                
199     }                                             
200         counter++;                                
201         // Loop checking, 05-Aug-2015, Vladimi    
202       } while (ThereAreOverlaps && counter < 1    
203                                                   
204     if (counter >= 1000)                          
205       {                                           
206         TooMuchIterations = true;                 
207         break;                                    
208       }                                           
209   }                                               
210       // Loop checking, 05-Aug-2015, Vladimir     
211     } while (TooMuchIterations);                  
212     return;                                       
213 }                                                 
214                                                   
215 void G4StatMFChannel::FragmentsMomenta(G4int N    
216                G4double T)                        
217 // Calculate fragments momenta at the breakup     
218 // Fragment kinetic energies are calculated ac    
219 // Boltzmann distribution at given temperature    
220 // NF is number of fragments                      
221 // idx is index of first fragment                 
222 {                                                 
223   G4double KinE = 1.5*T*NF;                       
224   G4ThreeVector p(0.,0.,0.);                      
225                                                   
226   if (NF <= 0) return;                            
227   else if (NF == 1)                               
228     {                                             
229       // We have only one fragment to deal wit    
230       p = std::sqrt(2.0*_theFragments[idx]->Ge    
231   *G4RandomDirection();                           
232       _theFragments[idx]->SetMomentum(p);         
233     }                                             
234   else if (NF == 2)                               
235     {                                             
236       // We have only two fragment to deal wit    
237       G4double M1 = _theFragments[idx]->GetNuc    
238       G4double M2 = _theFragments[idx+1]->GetN    
239       p = std::sqrt(2.0*KinE*(M1*M2)/(M1+M2))*    
240       _theFragments[idx]->SetMomentum(p);         
241       _theFragments[idx+1]->SetMomentum(-p);      
242     }                                             
243   else                                            
244     {                                             
245       // We have more than two fragments          
246       G4double AvailableE;                        
247       G4int i1,i2;                                
248       G4double SummedE;                           
249       G4ThreeVector SummedP(0.,0.,0.);            
250       do                                          
251   {                                               
252     // Fisrt sample momenta of NF-2 fragments     
253     // according to Boltzmann distribution        
254     AvailableE = 0.0;                             
255     SummedE = 0.0;                                
256     SummedP.setX(0.0);SummedP.setY(0.0);Summed    
257     for (G4int i = idx; i < idx+NF-2; ++i)        
258       {                                           
259         G4double E;                               
260         G4double RandE;                           
261         do                                        
262     {                                             
263       E = 9.0*G4UniformRand();                    
264       RandE = std::sqrt(0.5/E)*G4Exp(E-0.5)*G4    
265     }                                             
266         // Loop checking, 05-Aug-2015, Vladimi    
267         while (RandE > 1.0);                      
268         E *= T;                                   
269         p = std::sqrt(2.0*E*_theFragments[i]->    
270     *G4RandomDirection();                         
271         _theFragments[i]->SetMomentum(p);         
272         SummedE += E;                             
273         SummedP += p;                             
274       }                                           
275     // Calculate momenta of last two fragments    
276     // that constraints are satisfied             
277     i1 = idx+NF-2;  // before last fragment in    
278     i2 = idx+NF-1;  // last fragment index        
279     p = -SummedP;                                 
280     AvailableE = KinE - SummedE;                  
281     // Available Kinetic Energy should be shar    
282   }                                               
283       // Loop checking, 05-Aug-2015, Vladimir     
284       while (AvailableE <= p.mag2()/(2.0*(_the    
285             _theFragments[i2]->GetNuclearMass(    
286       G4double H = 1.0 + _theFragments[i2]->Ge    
287   /_theFragments[i1]->GetNuclearMass();           
288       G4double CTM12 = H*(1.0 - 2.0*_theFragme    
289         *AvailableE/p.mag2());                    
290       G4double CosTheta1;                         
291       G4double Sign;                              
292                                                   
293       if (CTM12 > 1.) {CosTheta1 = 1.;}           
294       else {                                      
295   do                                              
296     {                                             
297       do                                          
298         {                                         
299     CosTheta1 = 1.0 - 2.0*G4UniformRand();        
300         }                                         
301       // Loop checking, 05-Aug-2015, Vladimir     
302       while (CosTheta1*CosTheta1 < CTM12);        
303     }                                             
304   // Loop checking, 05-Aug-2015, Vladimir Ivan    
305   while (CTM12 >= 0.0 && CosTheta1 < 0.0);        
306       }                                           
307                                                   
308       if (CTM12 < 0.0) Sign = 1.0;                
309       else if (G4UniformRand() <= 0.5) Sign =     
310       else Sign = 1.0;                            
311                                                   
312       G4double P1 = (p.mag()*CosTheta1+Sign*st    
313                   *(CosTheta1*CosTheta1-CTM12)    
314       G4double P2 = std::sqrt(P1*P1+p.mag2() -    
315       G4double Phi = twopi*G4UniformRand();       
316       G4double SinTheta1 = std::sqrt(1.0 - Cos    
317       G4double CosPhi1 = std::cos(Phi);           
318       G4double SinPhi1 = std::sin(Phi);           
319       G4double CosPhi2 = -CosPhi1;                
320       G4double SinPhi2 = -SinPhi1;                
321       G4double CosTheta2 = (p.mag2() + P2*P2 -    
322       G4double SinTheta2 = 0.0;                   
323       if (CosTheta2 > -1.0 && CosTheta2 < 1.0)    
324   SinTheta2 = std::sqrt(1.0 - CosTheta2*CosThe    
325       }                                           
326       G4ThreeVector p1(P1*SinTheta1*CosPhi1,P1    
327       G4ThreeVector p2(P2*SinTheta2*CosPhi2,P2    
328       G4ThreeVector b(1.0,0.0,0.0);               
329                                                   
330       p1 = RotateMomentum(p,b,p1);                
331       p2 = RotateMomentum(p,b,p2);                
332                                                   
333       SummedP += p1 + p2;                         
334       SummedE += p1.mag2()/(2.0*_theFragments[    
335   p2.mag2()/(2.0*_theFragments[i2]->GetNuclear    
336                                                   
337       _theFragments[i1]->SetMomentum(p1);         
338       _theFragments[i2]->SetMomentum(p2);         
339                                                   
340     }                                             
341   return;                                         
342 }                                                 
343                                                   
344 void G4StatMFChannel::SolveEqOfMotion(G4int an    
345 // This method will find a solution of Newton'    
346 // for fragments in the self-consistent time-d    
347 {                                                 
348   G4Pow* g4calc = G4Pow::GetInstance();           
349   G4double CoulombEnergy = 0.6*CLHEP::elm_coup    
350     g4calc->A13(1.0+G4StatMFParameters::GetKap    
351     (G4StatMFParameters::Getr0()*g4calc->Z13(a    
352   if (CoulombEnergy <= 0.0) return;               
353                                                   
354   G4int Iterations = 0;                           
355   G4double TimeN = 0.0;                           
356   G4double TimeS = 0.0;                           
357   G4double DeltaTime = 10.0;                      
358   if (_NumOfChargedFragments > (G4int)Pos.size    
359     Pos.resize(_NumOfChargedFragments);           
360     Vel.resize(_NumOfChargedFragments);           
361     Accel.resize(_NumOfChargedFragments);         
362   }                                               
363                                                   
364   G4int i;                                        
365   for (i = 0; i < _NumOfChargedFragments; ++i)    
366     {                                             
367       Vel[i] = (1.0/(_theFragments[i]->GetNucl    
368   _theFragments[i]->GetMomentum();                
369       Pos[i] = _theFragments[i]->GetPosition()    
370     }                                             
371                                                   
372   G4ThreeVector distance(0.,0.,0.);               
373   G4ThreeVector force(0.,0.,0.);                  
374   G4ThreeVector SavedVel(0.,0.,0.);               
375   do {                                            
376     for (i = 0; i < _NumOfChargedFragments; ++    
377       {                                           
378   force.set(0.,0.,0.);                            
379   for (G4int j = 0; j < _NumOfChargedFragments    
380     {                                             
381       if (i != j)                                 
382         {                                         
383     distance = Pos[i] - Pos[j];                   
384     force += (_theFragments[i]->GetZ()*_theFra    
385         (distance.mag2()*distance.mag()))*dist    
386         }                                         
387     }                                             
388   Accel[i] = CLHEP::elm_coupling*CLHEP::fermi*    
389       }                                           
390                                                   
391     TimeN = TimeS + DeltaTime;                    
392                                                   
393     for ( i = 0; i < _NumOfChargedFragments; +    
394       {                                           
395   SavedVel = Vel[i];                              
396   Vel[i] += Accel[i]*(TimeN-TimeS);               
397   Pos[i] += (SavedVel+Vel[i])*(TimeN-TimeS)*0.    
398       }                                           
399     TimeS = TimeN;                                
400                                                   
401     // Loop checking, 05-Aug-2015, Vladimir Iv    
402   } while (Iterations++ < 100);                   
403                                                   
404   // Summed fragment kinetic energy               
405   G4double TotalKineticEnergy = 0.0;              
406   for (i = 0; i < _NumOfChargedFragments; ++i)    
407     {                                             
408       TotalKineticEnergy += _theFragments[i]->    
409   0.5*Vel[i].mag2();                              
410     }                                             
411   // Scaling of fragment velocities               
412   G4double KineticEnergy = 1.5*_NumOfChargedFr    
413   G4double Eta = std::pow(( CoulombEnergy + Ki    
414                                                   
415   // Finally calculate fragments momenta          
416   for (i = 0; i < _NumOfChargedFragments; ++i)    
417     {                                             
418       _theFragments[i]->SetMomentum((_theFragm    
419     }                                             
420   return;                                         
421 }                                                 
422                                                   
423 G4ThreeVector G4StatMFChannel::RotateMomentum(    
424                 G4ThreeVector V, G4ThreeVector    
425     // Rotates a 3-vector P to close momentum     
426 {                                                 
427   G4ThreeVector U = Pa.unit();                    
428                                                   
429   G4double Alpha1 = U * V;                        
430                                                   
431   G4double Alpha2 = std::sqrt(V.mag2() - Alpha    
432                                                   
433   G4ThreeVector N = (1./Alpha2)*U.cross(V);       
434                                                   
435   G4ThreeVector RotatedMomentum(                  
436         ( (V.x() - Alpha1*U.x())/Alpha2 ) * P.    
437         ( (V.y() - Alpha1*U.y())/Alpha2 ) * P.    
438         ( (V.z() - Alpha1*U.z())/Alpha2 ) * P.    
439         );                                        
440   return RotatedMomentum;                         
441 }                                                 
442                                                   
443