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Geant4/processes/hadronic/stopping/src/G4MuonMinusBoundDecay.cc

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Diff markup

Differences between /processes/hadronic/stopping/src/G4MuonMinusBoundDecay.cc (Version 11.3.0) and /processes/hadronic/stopping/src/G4MuonMinusBoundDecay.cc (Version 9.4.p2)


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 27 //--------------------------------------------    
 28 //                                                
 29 // GEANT4 Class header file                       
 30 //                                                
 31 // File name:  G4MuonMinusBoundDecay              
 32 //                                                
 33 // Author:        V.Ivanchenko (Vladimir.Ivant    
 34 //                                                
 35 // Creation date: 24 April 2012 on base of G4M    
 36 //                                                
 37 // Modified:                                      
 38 // 04/23/2013  K.Genser     Fixed a constant i    
 39 //                          as suggested by J     
 40 //                          Optimized and corr    
 41 // 04/30/2013  K.Genser     Improved GetMuonCa    
 42 //                          to take both Z & A    
 43 //                          Improved GetMuonDe    
 44 //                          Extracted Zeff int    
 45 // 10/08/2018  K.Genser     Improved accuracy     
 46 //                                                
 47 //--------------------------------------------    
 48                                                   
 49 #include "G4MuonMinusBoundDecay.hh"               
 50 #include "Randomize.hh"                           
 51 #include "G4RandomDirection.hh"                   
 52 #include "G4PhysicalConstants.hh"                 
 53 #include "G4SystemOfUnits.hh"                     
 54 #include "G4ThreeVector.hh"                       
 55 #include "G4NistManager.hh"                       
 56 #include "G4NucleiProperties.hh"                  
 57 #include "G4IonTable.hh"                          
 58 #include "G4MuonMinus.hh"                         
 59 #include "G4Electron.hh"                          
 60 #include "G4NeutrinoMu.hh"                        
 61 #include "G4AntiNeutrinoE.hh"                     
 62 #include "G4Log.hh"                               
 63                                                   
 64 //....oooOO0OOooo........oooOO0OOooo........oo    
 65                                                   
 66 G4MuonMinusBoundDecay::G4MuonMinusBoundDecay()    
 67   : G4HadronicInteraction("muMinusBoundDeacy")    
 68 {                                                 
 69   fMuMass = G4MuonMinus::MuonMinus()->GetPDGMa    
 70 }                                                 
 71                                                   
 72 //....oooOO0OOooo........oooOO0OOooo........oo    
 73                                                   
 74 G4MuonMinusBoundDecay::~G4MuonMinusBoundDecay(    
 75 {}                                                
 76                                                   
 77 //....oooOO0OOooo........oooOO0OOooo........oo    
 78                                                   
 79 G4HadFinalState*                                  
 80 G4MuonMinusBoundDecay::ApplyYourself(const G4H    
 81                                      G4Nucleus    
 82 {                                                 
 83   result.Clear();                                 
 84   G4int Z = targetNucleus.GetZ_asInt();           
 85   G4int A = targetNucleus.GetA_asInt();           
 86                                                   
 87   // Decide on Decay or Capture, and doit.        
 88   G4double lambdac  = GetMuonCaptureRate(Z, A)    
 89   G4double lambdad  = GetMuonDecayRate(Z, A, f    
 90                                        targetN    
 91   G4double lambda   = lambdac + lambdad;          
 92                                                   
 93   // ===  sample capture  time and change time    
 94   // ===  this is needed for the case when bou    
 95   // ===  but muon is capruted by the nucleus     
 96                                                   
 97   G4HadProjectile* p = const_cast<G4HadProject    
 98   G4double time = p->GetGlobalTime() - G4Log(G    
 99   p->SetGlobalTime(time);                         
100                                                   
101   //G4cout << "lambda= " << lambda << " lambda    
102   //<< " t= " << time << G4endl;                  
103                                                   
104   // cascade                                      
105   if( G4UniformRand()*lambda < lambdac) {         
106     result.SetStatusChange(isAlive);              
107                                                   
108   } else {                                        
109                                                   
110     // Simulation on Decay of mu- on a K-shell    
111     result.SetStatusChange(stopAndKill);          
112     G4double xmax = 1 + electron_mass_c2*elect    
113     G4double xmin = 2.0*electron_mass_c2/fMuMa    
114     G4double KEnergy = projectile.GetBoundEner    
115                                                   
116     /*                                            
117       G4cout << "G4MuonMinusBoundDecay::ApplyY    
118       << " XMAX= " << xmax << " Ebound= " << K    
119     */                                            
120     G4double pmu = std::sqrt(KEnergy*(KEnergy     
121     G4double emu = KEnergy + fMuMass;             
122     G4ThreeVector dir = G4RandomDirection();      
123     G4LorentzVector MU(pmu*dir, emu);             
124     G4ThreeVector bst = MU.boostVector();         
125                                                   
126     G4double Eelect, Pelect, x, ecm;              
127     G4LorentzVector EL, NN;                       
128     // Calculate electron energy                  
129     // these do/while loops are safe              
130     do {                                          
131       do {                                        
132         x = xmin + (xmax-xmin)*G4UniformRand()    
133       } while (G4UniformRand() > (3.0 - 2.0*x)    
134       Eelect = x*fMuMass*0.5;                     
135       Pelect = 0.0;                               
136       if(Eelect > electron_mass_c2) {             
137         Pelect = std::sqrt(Eelect*Eelect - ele    
138       } else {                                    
139         Pelect = 0.0;                             
140         Eelect = electron_mass_c2;                
141       }                                           
142       dir = G4RandomDirection();                  
143       EL = G4LorentzVector(Pelect*dir,Eelect);    
144       EL.boost(bst);                              
145       Eelect = EL.e() - electron_mass_c2 - 2.0    
146       //                                          
147       // Calculate rest frame parameters of 2     
148       //                                          
149       NN = MU - EL;                               
150       ecm = NN.mag2();                            
151       // Loop checking, 06-Aug-2015, Vladimir     
152     } while (Eelect < 0.0 || ecm < 0.0);          
153                                                   
154     //                                            
155     // Create electron                            
156     //                                            
157     G4DynamicParticle* dp = new G4DynamicParti    
158                                                   
159                                                   
160                                                   
161     AddNewParticle(dp, time);                     
162     //                                            
163     // Create Neutrinos                           
164     //                                            
165     ecm = 0.5*std::sqrt(ecm);                     
166     bst = NN.boostVector();                       
167     G4ThreeVector p1 = ecm * G4RandomDirection    
168     G4LorentzVector N1 = G4LorentzVector(p1,ec    
169     N1.boost(bst);                                
170     dp = new G4DynamicParticle(G4AntiNeutrinoE    
171     AddNewParticle(dp, time);                     
172     NN -= N1;                                     
173     dp = new G4DynamicParticle(G4NeutrinoMu::N    
174     AddNewParticle(dp, time);                     
175   }                                               
176   return &result;                                 
177 }                                                 
178                                                   
179 //....oooOO0OOooo........oooOO0OOooo........oo    
180                                                   
181 G4double G4MuonMinusBoundDecay::GetMuonCapture    
182 {                                                 
183                                                   
184   // Initialize data                              
185                                                   
186   // Mu- capture data from                        
187   // T. Suzuki, D. F. Measday, J.P. Roalsvig P    
188   // weighted average of the two most precise     
189                                                   
190   // Data for Hydrogen from Phys. Rev. Lett. 9    
191   // Data for Helium from D.F. Measday Phys. R    
192                                                   
193   struct capRate {                                
194     G4int        Z;                               
195     G4int        A;                               
196     G4double cRate;                               
197     G4double cRErr;                               
198   };                                              
199                                                   
200   // this struct has to be sorted by Z when in    
201   // loop once Z is above the stored value; cR    
202   // are included for completeness and future     
203                                                   
204   static const capRate capRates [] = {            
205     {  1,   1,  0.000725, 0.000017 },             
206     {  2,   3,  0.002149, 0.00017 },              
207     {  2,   4,  0.000356, 0.000026 },             
208     {  3,   6,  0.004647, 0.00012 },              
209     {  3,   7,  0.002229, 0.00012 },              
210     {  4,   9,  0.006107, 0.00019 },              
211     {  5,  10,  0.02757 , 0.00063 },              
212     {  5,  11,  0.02188 , 0.00064 },              
213     {  6,  12,  0.03807 , 0.00031 },              
214     {  6,  13,  0.03474 , 0.00034 },              
215     {  7,  14,  0.06885 , 0.00057 },              
216     {  8,  16,  0.10242 , 0.00059 },              
217     {  8,  18,  0.0880  , 0.0015  },              
218     {  9,  19,  0.22905 , 0.00099 },              
219     { 10,  20,  0.2288  , 0.0045 },               
220     { 11,  23,  0.3773  , 0.0014 },               
221     { 12,  24,  0.4823  , 0.0013 },               
222     { 13,  27,  0.6985  , 0.0012 },               
223     { 14,  28,  0.8656  , 0.0015 },               
224     { 15,  31,  1.1681  , 0.0026 },               
225     { 16,  32,  1.3510  , 0.0029 },               
226     { 17,  35,  1.800   , 0.050 },                
227     { 17,  37,  1.250   , 0.050 },                
228     { 18,  40,  1.2727  , 0.0650 },               
229     { 19,  39,  1.8492  , 0.0050 },               
230     { 20,  40,  2.5359  , 0.0070 },               
231     { 21,  45,  2.711   , 0.025 },                
232     { 22,  48,  2.5908  , 0.0115 },               
233     { 23,  51,  3.073   , 0.022 },                
234     { 24,  50,  3.825   , 0.050 },                
235     { 24,  52,  3.465   , 0.026 },                
236     { 24,  53,  3.297   , 0.045 },                
237     { 24,  54,  3.057   , 0.042 },                
238     { 25,  55,  3.900   , 0.030 },                
239     { 26,  56,  4.408   , 0.022 },                
240     { 27,  59,  4.945   , 0.025 },                
241     { 28,  58,  6.11    , 0.10 },                 
242     { 28,  60,  5.56    , 0.10 },                 
243     { 28,  62,  4.72    , 0.10 },                 
244     { 29,  63,  5.691   , 0.030 },                
245     { 30,  66,  5.806   , 0.031 },                
246     { 31,  69,  5.700   , 0.060 },                
247     { 32,  72,  5.561   , 0.031 },                
248     { 33,  75,  6.094   , 0.037 },                
249     { 34,  80,  5.687   , 0.030 },                
250     { 35,  79,  7.223   , 0.28 },                 
251     { 35,  81,  7.547   , 0.48 },                 
252     { 37,  85,  6.89    , 0.14 },                 
253     { 38,  88,  6.93    , 0.12 },                 
254     { 39,  89,  7.89    , 0.11 },                 
255     { 40,  91,  8.620   , 0.053 },                
256     { 41,  93, 10.38    , 0.11 },                 
257     { 42,  96,  9.298   , 0.063 },                
258     { 45, 103, 10.010   , 0.045 },                
259     { 46, 106, 10.000   , 0.070 },                
260     { 47, 107, 10.869   , 0.095 },                
261     { 48, 112, 10.624   , 0.094 },                
262     { 49, 115, 11.38    , 0.11 },                 
263     { 50, 119, 10.60    , 0.11 },                 
264     { 51, 121, 10.40    , 0.12 },                 
265     { 52, 128,  9.174   , 0.074 },                
266     { 53, 127, 11.276   , 0.098 },                
267     { 55, 133, 10.98    , 0.25 },                 
268     { 56, 138, 10.112   , 0.085 },                
269     { 57, 139, 10.71    , 0.10 },                 
270     { 58, 140, 11.501   , 0.087 },                
271     { 59, 141, 13.45    , 0.13 },                 
272     { 60, 144, 12.35    , 0.13 },                 
273     { 62, 150, 12.22    , 0.17 },                 
274     { 64, 157, 12.00    , 0.13 },                 
275     { 65, 159, 12.73    , 0.13 },                 
276     { 66, 163, 12.29    , 0.18 },                 
277     { 67, 165, 12.95    , 0.13 },                 
278     { 68, 167, 13.04    , 0.27 },                 
279     { 72, 178, 13.03    , 0.21 },                 
280     { 73, 181, 12.86    , 0.13 },                 
281     { 74, 184, 12.76    , 0.16 },                 
282     { 79, 197, 13.35    , 0.10 },                 
283     { 80, 201, 12.74    , 0.18 },                 
284     { 81, 205, 13.85    , 0.17 },                 
285     { 82, 207, 13.295   , 0.071 },                
286     { 83, 209, 13.238   , 0.065 },                
287     { 90, 232, 12.555   , 0.049 },                
288     { 92, 238, 12.592   , 0.035 },                
289     { 92, 233, 14.27    , 0.15 },                 
290     { 92, 235, 13.470   , 0.085 },                
291     { 92, 236, 13.90    , 0.40 },                 
292     { 93, 237, 13.58    , 0.18 },                 
293     { 94, 239, 13.90    , 0.20 },                 
294     { 94, 242, 12.86    , 0.19 }                  
295   };                                              
296                                                   
297   G4double lambda = -1.;                          
298                                                   
299   size_t nCapRates = sizeof(capRates)/sizeof(c    
300   for (size_t j = 0; j < nCapRates; ++j) {        
301     if( capRates[j].Z == Z && capRates[j].A ==    
302       lambda = capRates[j].cRate / microsecond    
303       break;                                      
304     }                                             
305     // make sure the data is sorted for the ne    
306     if (capRates[j].Z > Z) {break;}               
307   }                                               
308                                                   
309   if (lambda < 0.) {                              
310                                                   
311     // ==  Mu capture lifetime (Goulard and Pr    
312                                                   
313     static const G4double b0a = -0.03;            
314     static const G4double b0b = -0.25;            
315     static const G4double b0c =  3.24;            
316     static const G4double t1 = 875.e-9; // -10    
317     G4double r1 = GetMuonZeff(Z);                 
318     G4double zeff2 = r1 * r1;                     
319                                                   
320     // ^-4 -> ^-5 suggested by user               
321     G4double xmu = zeff2 * 2.663e-5;              
322     G4double a2ze = 0.5 *G4double(A) / G4doubl    
323     G4double r2 = 1.0 - xmu;                      
324     lambda = t1 * zeff2 * zeff2 * (r2 * r2) *     
325       (a2ze * b0a + 1.0 - (a2ze - 1.0) * b0b -    
326        G4double(2 * (A - Z)  + std::abs(a2ze -    
327                                                   
328   }                                               
329                                                   
330   return lambda;                                  
331                                                   
332 }                                                 
333                                                   
334 //....oooOO0OOooo........oooOO0OOooo........oo    
335                                                   
336                                                   
337 G4double G4MuonMinusBoundDecay::GetMuonZeff(G4    
338 {                                                 
339                                                   
340   // ==  Effective charges from                   
341   // "Total Nuclear Capture Rates for Negative    
342   // T. Suzuki, D. F. Measday, J.P. Roalsvig P    
343   // and if not present from                      
344   // Ford and Wills Nucl Phys 35(1962)295 or i    
345                                                   
346   static const G4int maxZ = 100;                  
347   static const G4double zeff[] =                  
348     {  0.,                                        
349        1.00, 1.98, 2.94, 3.89, 4.81, 5.72, 6.6    
350        9.95,10.69,11.48,12.22,12.90,13.64,14.2    
351        16.77,17.38,18.04,18.49,19.06,19.59,20.    
352        22.02,22.43,22.84,23.24,23.65,24.06,24.    
353        25.99,26.37,26.69,27.00,27.32,27.63,27.    
354        28.79,29.03,29.27,29.51,29.75,29.99,30.    
355        30.85,31.01,31.18,31.34,31.48,31.62,31.    
356        32.33,32.47,32.61,32.76,32.94,33.11,33.    
357        34.21,34.18,34.00,34.10,34.21,34.31,34.    
358        34.84,34.94,35.05,35.16,35.25,35.36,35.    
359                                                   
360   G4int Z = std::max(std::min(ZZ, maxZ), 1);      
361   return zeff[Z];                                 
362 }                                                 
363                                                   
364 G4double G4MuonMinusBoundDecay::GetMuonDecayRa    
365 {                                                 
366   G4int A = G4lrint(G4NistManager::Instance()-    
367   return GetMuonDecayRate(Z, A, G4MuonMinus::M    
368                           G4NucleiProperties::    
369 }                                                 
370                                                   
371 G4double G4MuonMinusBoundDecay::GetMuonDecayRa    
372                                                   
373                                                   
374 {                                                 
375   // Decay time correction based on               
376   // H. C. Von Baeyer and D. Leiter, Phys. Rev    
377   // replacing N.C.Mukhopadhyay Phys. Rep. 30     
378   // for Z < 14 inspired by report 2049           
379   // Lambda(bound)/Lambda(free) = 1-(0.5+0.06*    
380                                                   
381   // PDG 2012 muon lifetime value is 2.1969811    
382   // which when inverted gives       0.4551700    
383                                                   
384   // we pass known alraedy in ApplyYourself mu    
385   // avoid refetching/recalculations              
386                                                   
387   struct decRate {                                
388     G4int         Z;                              
389     G4int         A;                              
390     G4double  dRate;                              
391     G4double  dRErr;                              
392   };                                              
393                                                   
394   // this struct has to be sorted by Z when in    
395   // loop once Z is above the stored value        
396                                                   
397   static const decRate decRates [] = {            
398     {  0,  0, 0.45517005, 0.00000046 } // free    
399   };                                              
400                                                   
401   G4double lambda = -1.;                          
402   if (Z == 0 && A == 0) {lambda =  decRates[0]    
403                                                   
404   // size_t nDecRates = sizeof(decRates)/sizeo    
405   // for (size_t j = 0; j < nDecRates; ++j) {     
406   //   if( decRates[j].Z == Z && decRates[j].A    
407   //     lambda = decRates[j].cRate / microsec    
408   //     break;                                   
409   //   }                                          
410   //   // make sure the data is sorted for the    
411   //   if (decRates[j].Z > Z) {break;}            
412   // }                                            
413                                                   
414   // we'll use the above code once we have the    
415   // if we had one value we would just assign     
416   // if (Z == 1 && A == 1) {lambda =  decRates    
417                                                   
418   if (lambda < 0.) {                              
419     const G4double freeMuonDecayRate =  0.4551    
420     lambda = 1.0;                                 
421     G4double x = Z*fine_structure_const;          
422     if (Z<14) {                                   
423       // using the Phys. Rev. formula             
424       lambda -= x * x * (0.5 + 0.06 * muMass/n    
425     } else {                                      
426       // based on a fit to the data ref. in Ph    
427       lambda -=  x * x * (0.868699 - x * 0.708    
428     }                                             
429     lambda *= freeMuonDecayRate;                  
430   }                                               
431   return lambda;                                  
432 }                                                 
433                                                   
434 //....oooOO0OOooo........oooOO0OOooo........oo    
435                                                   
436 void G4MuonMinusBoundDecay::ModelDescription(s    
437 {                                                 
438   outFile << " Sample probabilities of mu- nuc    
439           << "  from K-shell orbit.\n"            
440           << " Time of projectile is changed t    
441           << "  of muonic atom.\n"                
442           << " If decay is sampled primary sta    
443           << "  else - isAlive.\n"                
444           << " Mainly based on:\n"                
445           << "  H.C. Von Baeyer and D.Leiter,     
446           << "  T.Suzuki, D.F.Measday, J.P.Roa    
447           << " with an emprical fit to the Huf    
448           << " from the above review\n";          
449 }                                                 
450                                                   
451 //....oooOO0OOooo........oooOO0OOooo........oo    
452