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Geant4/particles/management/src/G4MuonDecayChannelWithSpin.cc

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Differences between /particles/management/src/G4MuonDecayChannelWithSpin.cc (Version 11.3.0) and /particles/management/src/G4MuonDecayChannelWithSpin.cc (Version 8.2.p1)


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 25 //                                                 25 //
 26 // G4MuonDecayChannelWithSpin class implementa <<  26 // ------------------------------------------------------------
                                                   >>  27 //      GEANT 4 class header file
                                                   >>  28 //
                                                   >>  29 //      History:
                                                   >>  30 //               17 August 2004 P.Gumplinger and T.MacPhail
                                                   >>  31 //               samples Michel spectrum including 1st order
                                                   >>  32 //               radiative corrections
                                                   >>  33 //               Reference: Florian Scheck "Muon Physics", in Physics Reports
                                                   >>  34 //                          (Review Section of Physics Letters) 44, No. 4 (1978)
                                                   >>  35 //                          187-248. North-Holland Publishing Company, Amsterdam
                                                   >>  36 //                          at page 210 cc.
                                                   >>  37 //
                                                   >>  38 //                          W.E. Fisher and F. Scheck, Nucl. Phys. B83 (1974) 25.
                                                   >>  39 //
                                                   >>  40 // ------------------------------------------------------------
 27 //                                                 41 //
 28 // References:                                 << 
 29 // - Florian Scheck "Muon Physics", in Physics << 
 30 //   (Review Section of Physics Letters) 44, N << 
 31 //   187-248. North-Holland Publishing Company << 
 32 // - W.E. Fisher and F. Scheck, Nucl. Phys. B8 << 
 33                                                << 
 34 // Authors: P.Gumplinger and T.MacPhail, 17 Au << 
 35 // ------------------------------------------- << 
 36                                                << 
 37 #include "G4MuonDecayChannelWithSpin.hh"           42 #include "G4MuonDecayChannelWithSpin.hh"
 38                                                    43 
                                                   >>  44 #include "Randomize.hh"
 39 #include "G4DecayProducts.hh"                      45 #include "G4DecayProducts.hh"
 40 #include "G4LorentzVector.hh"                      46 #include "G4LorentzVector.hh"
 41 #include "G4PhysicalConstants.hh"              << 
 42 #include "G4SystemOfUnits.hh"                  << 
 43 #include "Randomize.hh"                        << 
 44                                                    47 
 45 G4MuonDecayChannelWithSpin::G4MuonDecayChannel <<  48 G4MuonDecayChannelWithSpin::G4MuonDecayChannelWithSpin(const G4String& theParentName, 
 46                                                <<  49                    G4double        theBR)
 47   : G4MuonDecayChannel(theParentName, theBR)   <<  50                            : G4MuonDecayChannel(theParentName,theBR)
 48 {}                                             <<  51 {
                                                   >>  52 }
 49                                                    53 
 50 G4MuonDecayChannelWithSpin&                    <<  54 G4MuonDecayChannelWithSpin::~G4MuonDecayChannelWithSpin()
 51 G4MuonDecayChannelWithSpin::operator=(const G4 << 
 52 {                                                  55 {
 53   if (this != &right) {                        << 
 54     kinematics_name = right.kinematics_name;   << 
 55     verboseLevel = right.verboseLevel;         << 
 56     rbranch = right.rbranch;                   << 
 57                                                << 
 58     // copy parent name                        << 
 59     delete parent_name;                        << 
 60     parent_name = new G4String(*right.parent_n << 
 61                                                << 
 62     // clear daughters_name array              << 
 63     ClearDaughtersName();                      << 
 64                                                << 
 65     // recreate array                          << 
 66     numberOfDaughters = right.numberOfDaughter << 
 67     if (numberOfDaughters > 0) {               << 
 68       daughters_name = new G4String*[numberOfD << 
 69       // copy daughters name                   << 
 70       for (G4int index = 0; index < numberOfDa << 
 71         daughters_name[index] = new G4String(* << 
 72       }                                        << 
 73     }                                          << 
 74   }                                            << 
 75   return *this;                                << 
 76 }                                                  56 }
 77                                                    57 
 78 G4DecayProducts* G4MuonDecayChannelWithSpin::D <<  58 G4DecayProducts *G4MuonDecayChannelWithSpin::DecayIt(G4double) 
 79 {                                                  59 {
 80   // This version assumes V-A coupling with 1s     60   // This version assumes V-A coupling with 1st order radiative correctons,
 81   //              the standard model Michel pa     61   //              the standard model Michel parameter values, but
 82   //              gives incorrect energy spect     62   //              gives incorrect energy spectrum for neutrinos
 83                                                    63 
 84 #ifdef G4VERBOSE                                   64 #ifdef G4VERBOSE
 85   if (GetVerboseLevel() > 1) G4cout << "G4Muon <<  65   if (GetVerboseLevel()>1) G4cout << "G4MuonDecayChannelWithSpin::DecayIt ";
 86 #endif                                             66 #endif
 87                                                    67 
 88   CheckAndFillParent();                        <<  68   if (parent == 0) FillParent();  
 89   CheckAndFillDaughters();                     <<  69   if (daughters == 0) FillDaughters();
 90                                                    70 
 91   // parent mass                                   71   // parent mass
 92   G4double parentmass = G4MT_parent->GetPDGMas <<  72   G4double parentmass = parent->GetPDGMass();
 93                                                    73 
 94   G4double EMMU = parentmass;                  <<  74   EMMU = parentmass;
 95                                                    75 
 96   // daughters'mass                            <<  76   //daughters'mass
 97   G4double daughtermass[3];                    <<  77   G4double daughtermass[3]; 
 98   // G4double sumofdaughtermass = 0.0;         <<  78   G4double sumofdaughtermass = 0.0;
 99   for (G4int index = 0; index < 3; ++index) {  <<  79   for (G4int index=0; index<3; index++){
100     daughtermass[index] = G4MT_daughters[index <<  80     daughtermass[index] = daughters[index]->GetPDGMass();
101     // sumofdaughtermass += daughtermass[index <<  81     sumofdaughtermass += daughtermass[index];
102   }                                                82   }
103                                                    83 
104   G4double EMASS = daughtermass[0];            <<  84   EMASS = daughtermass[0];
105                                                    85 
106   // create parent G4DynamicParticle at rest   <<  86   //create parent G4DynamicParticle at rest
107   G4ThreeVector dummy;                             87   G4ThreeVector dummy;
108   auto parentparticle = new G4DynamicParticle( <<  88   G4DynamicParticle * parentparticle = new G4DynamicParticle( parent, dummy, 0.0);
109   // create G4Decayproducts                    <<  89   //create G4Decayproducts
110   auto products = new G4DecayProducts(*parentp <<  90   G4DecayProducts *products = new G4DecayProducts(*parentparticle);
111   delete parentparticle;                           91   delete parentparticle;
112                                                    92 
113   // calculate electron energy                 <<  93   // calcurate electron energy
114                                                    94 
115   G4double michel_rho = 0.75;  // Standard Mod <<  95   G4double michel_rho   = 0.75; //Standard Model Michel rho
116   G4double michel_delta = 0.75;  // Standard M <<  96   G4double michel_delta = 0.75; //Standard Model Michel delta
117   G4double michel_xsi = 1.00;  // Standard Mod <<  97   G4double michel_xsi   = 1.00; //Standard Model Michel xsi
118   G4double michel_eta = 0.00;  // Standard Mod <<  98   G4double michel_eta   = 0.00; //Standard Model eta
119                                                    99 
120   G4double rndm, x, ctheta;                       100   G4double rndm, x, ctheta;
121                                                   101 
122   G4double FG;                                 << 102   G4double FG; 
123   G4double FG_max = 2.00;                         103   G4double FG_max = 2.00;
124                                                   104 
125   G4double W_mue = (EMMU * EMMU + EMASS * EMAS << 105   G4double W_mue  = (EMMU*EMMU+EMASS*EMASS)/(2.*EMMU);
126   G4double x0 = EMASS / W_mue;                 << 106   G4double x0     =           EMASS/W_mue;
127                                                   107 
128   G4double x0_squared = x0 * x0;               << 108   G4double x0_squared = x0*x0;
129                                                   109 
130   // *****************************************    110   // ***************************************************
131   //     x0 <= x <= 1.   and   -1 <= y <= 1       111   //     x0 <= x <= 1.   and   -1 <= y <= 1
132   //                                              112   //
133   //     F(x,y) = f(x)*g(x,y);   g(x,y) = 1.+g    113   //     F(x,y) = f(x)*g(x,y);   g(x,y) = 1.+g(x)*y
134   // *****************************************    114   // ***************************************************
135                                                   115 
136   // ***** sampling F(x,y) directly (brute for    116   // ***** sampling F(x,y) directly (brute force) *****
137                                                   117 
138   const std::size_t MAX_LOOP = 10000;          << 118   do{
139   for (std::size_t loop_count = 0; loop_count  << 119 
140     // Sample the positron energy by sampling     120     // Sample the positron energy by sampling from F
141                                                   121 
142     rndm = G4UniformRand();                       122     rndm = G4UniformRand();
143                                                   123 
144     x = x0 + rndm * (1. - x0);                 << 124     x = x0 + rndm*(1.-x0);
145                                                   125 
146     G4double x_squared = x * x;                << 126     G4double x_squared = x*x;
147                                                   127 
148     G4double F_IS, F_AS, G_IS, G_AS;              128     G4double F_IS, F_AS, G_IS, G_AS;
149                                                   129 
150     F_IS = 1. / 6. * (-2. * x_squared + 3. * x << 130     F_IS = 1./6.*(-2.*x_squared+3.*x-x0_squared);
151     F_AS = 1. / 6. * std::sqrt(x_squared - x0_ << 131     F_AS = 1./6.*std::sqrt(x_squared-x0_squared)*(2.*x-2.+std::sqrt(1.-x0_squared));
152                                                   132 
153     G_IS = 2. / 9. * (michel_rho - 0.75) * (4. << 133     G_IS = 2./9.*(michel_rho-0.75)*(4.*x_squared-3.*x-x0_squared);
154     G_IS = G_IS + michel_eta * (1. - x) * x0;  << 134     G_IS = G_IS + michel_eta*(1.-x)*x0;
155                                                   135 
156     G_AS = 3. * (michel_xsi - 1.) * (1. - x);  << 136     G_AS = 3.*(michel_xsi-1.)*(1.-x);
157     G_AS =                                     << 137     G_AS = G_AS+2.*(michel_xsi*michel_delta-0.75)*(4.*x-4.+std::sqrt(1.-x0_squared));
158       G_AS + 2. * (michel_xsi * michel_delta - << 138     G_AS = 1./9.*std::sqrt(x_squared-x0_squared)*G_AS;
159     G_AS = 1. / 9. * std::sqrt(x_squared - x0_ << 
160                                                   139 
161     F_IS = F_IS + G_IS;                           140     F_IS = F_IS + G_IS;
162     F_AS = F_AS + G_AS;                           141     F_AS = F_AS + G_AS;
163                                                   142 
164     // *** Radiative Corrections ***              143     // *** Radiative Corrections ***
165                                                   144 
166     const G4double omega = std::log(EMMU / EMA << 145     G4double R_IS = F_c(x,x0);
167     G4double R_IS = F_c(x, x0, omega);         << 
168                                                   146 
169     G4double F = 6. * F_IS + R_IS / std::sqrt( << 147     G4double F = 6.*F_IS + R_IS/std::sqrt(x_squared-x0_squared);
170                                                   148 
171     // *** Radiative Corrections ***              149     // *** Radiative Corrections ***
172                                                   150 
173     G4double R_AS = F_theta(x, x0, omega);     << 151     G4double R_AS = F_theta(x,x0);
174                                                   152 
175     rndm = G4UniformRand();                       153     rndm = G4UniformRand();
176                                                   154 
177     ctheta = 2. * rndm - 1.;                   << 155     ctheta = 2.*rndm-1.;
178                                                   156 
179     G4double G = 6. * F_AS - R_AS / std::sqrt( << 157     G4double G = 6.*F_AS - R_AS/std::sqrt(x_squared-x0_squared);
180                                                   158 
181     FG = std::sqrt(x_squared - x0_squared) * F << 159     FG = std::sqrt(x_squared-x0_squared)*F*(1.+(G/F)*ctheta);
182                                                   160 
183     if (FG > FG_max) {                         << 161     if(FG>FG_max){
184       G4Exception("G4MuonDecayChannelWithSpin: << 162       G4cout<<"***Problem in Muon Decay *** : FG > FG_max"<<G4endl;
185                   "Problem in Muon Decay: FG > << 
186       FG_max = FG;                                163       FG_max = FG;
187     }                                             164     }
188                                                   165 
189     rndm = G4UniformRand();                       166     rndm = G4UniformRand();
190                                                   167 
191     if (FG >= rndm * FG_max) break;            << 168   }while(FG<rndm*FG_max);
192   }                                            << 
193                                                   169 
194   G4double energy = x * W_mue;                    170   G4double energy = x * W_mue;
195                                                   171 
196   rndm = G4UniformRand();                         172   rndm = G4UniformRand();
197                                                   173 
198   G4double phi = twopi * rndm;                    174   G4double phi = twopi * rndm;
199                                                   175 
200   if (energy < EMASS) energy = EMASS;          << 176   if(energy < EMASS) energy = EMASS;
201                                                   177 
202   // Calculate daughter momentum               << 178   // calculate daughter momentum
203   G4double daughtermomentum[3];                   179   G4double daughtermomentum[3];
204                                                   180 
205   daughtermomentum[0] = std::sqrt(energy * ene << 181   daughtermomentum[0] = std::sqrt(energy*energy - EMASS*EMASS);
206                                                   182 
207   G4double stheta = std::sqrt(1. - ctheta * ct << 183   G4double stheta = std::sqrt(1.-ctheta*ctheta);
208   G4double cphi = std::cos(phi);                  184   G4double cphi = std::cos(phi);
209   G4double sphi = std::sin(phi);                  185   G4double sphi = std::sin(phi);
210                                                   186 
211   // Coordinates of the decay positron with re << 187   //Coordinates of the decay positron with respect to the muon spin
212   G4double px = stheta * cphi;                 << 188 
213   G4double py = stheta * sphi;                 << 189   G4double px = stheta*cphi;
                                                   >> 190   G4double py = stheta*sphi;
214   G4double pz = ctheta;                           191   G4double pz = ctheta;
215                                                   192 
216   G4ThreeVector direction0(px, py, pz);        << 193   G4ThreeVector direction0(px,py,pz);
217                                                   194 
218   direction0.rotateUz(parent_polarization);       195   direction0.rotateUz(parent_polarization);
219                                                   196 
220   auto daughterparticle0 =                     << 197   G4DynamicParticle * daughterparticle0 
221     new G4DynamicParticle(G4MT_daughters[0], d << 198     = new G4DynamicParticle( daughters[0], daughtermomentum[0]*direction0);
222                                                   199 
223   products->PushProducts(daughterparticle0);      200   products->PushProducts(daughterparticle0);
224                                                   201 
                                                   >> 202 
225   // daughter 1 ,2 (neutrinos)                    203   // daughter 1 ,2 (neutrinos)
226   // create neutrinos in the C.M frame of two     204   // create neutrinos in the C.M frame of two neutrinos
227   G4double energy2 = parentmass - energy;      << 205   G4double energy2 = parentmass*(1.0 - x/2.0); 
228   G4double vmass = std::sqrt((energy2 - daught << 206   G4double vmass   = std::sqrt((energy2-daughtermomentum[0])*(energy2+daughtermomentum[0]));
229   G4double beta = -1.0 * daughtermomentum[0] / << 207   G4double beta = -1.0*daughtermomentum[0]/energy2;
230   G4double costhetan = 2. * G4UniformRand() -  << 208   G4double costhetan = 2.*G4UniformRand()-1.0;
231   G4double sinthetan = std::sqrt((1.0 - costhe << 209   G4double sinthetan = std::sqrt((1.0-costhetan)*(1.0+costhetan));
232   G4double phin = twopi * G4UniformRand() * ra << 210   G4double phin  = twopi*G4UniformRand()*rad;
233   G4double sinphin = std::sin(phin);              211   G4double sinphin = std::sin(phin);
234   G4double cosphin = std::cos(phin);              212   G4double cosphin = std::cos(phin);
235                                                   213 
236   G4ThreeVector direction1(sinthetan * cosphin << 214   G4ThreeVector direction1(sinthetan*cosphin,sinthetan*sinphin,costhetan);
237   auto daughterparticle1 = new G4DynamicPartic << 215   G4DynamicParticle * daughterparticle1 
238   auto daughterparticle2 =                     << 216     = new G4DynamicParticle( daughters[1], direction1*(vmass/2.));
239     new G4DynamicParticle(G4MT_daughters[2], d << 217   G4DynamicParticle * daughterparticle2
                                                   >> 218     = new G4DynamicParticle( daughters[2], direction1*(-1.0*vmass/2.));
240                                                   219 
241   // boost to the muon rest frame                 220   // boost to the muon rest frame
242   G4LorentzVector p4;                             221   G4LorentzVector p4;
243   p4 = daughterparticle1->Get4Momentum();         222   p4 = daughterparticle1->Get4Momentum();
244   p4.boost(direction0.x() * beta, direction0.y << 223   p4.boost( direction0.x()*beta, direction0.y()*beta, direction0.z()*beta);
245   daughterparticle1->Set4Momentum(p4);            224   daughterparticle1->Set4Momentum(p4);
246   p4 = daughterparticle2->Get4Momentum();         225   p4 = daughterparticle2->Get4Momentum();
247   p4.boost(direction0.x() * beta, direction0.y << 226   p4.boost( direction0.x()*beta, direction0.y()*beta, direction0.z()*beta);
248   daughterparticle2->Set4Momentum(p4);            227   daughterparticle2->Set4Momentum(p4);
249   products->PushProducts(daughterparticle1);      228   products->PushProducts(daughterparticle1);
250   products->PushProducts(daughterparticle2);      229   products->PushProducts(daughterparticle2);
251   daughtermomentum[1] = daughterparticle1->Get    230   daughtermomentum[1] = daughterparticle1->GetTotalMomentum();
252   daughtermomentum[2] = daughterparticle2->Get    231   daughtermomentum[2] = daughterparticle2->GetTotalMomentum();
253                                                   232 
254   // output message                               233   // output message
255 #ifdef G4VERBOSE                                  234 #ifdef G4VERBOSE
256   if (GetVerboseLevel() > 1) {                 << 235   if (GetVerboseLevel()>1) {
257     G4cout << "G4MuonDecayChannelWithSpin::Dec    236     G4cout << "G4MuonDecayChannelWithSpin::DecayIt ";
258     G4cout << "  create decay products in rest << 237     G4cout << "  create decay products in rest frame " <<G4endl;
259     G4double TT = daughterparticle0->GetTotalE << 238     products->DumpInfo();
260                   + daughterparticle2->GetTota << 
261     G4cout << "e  " << daughterparticle0->GetT << 
262     G4cout << "nu1" << daughterparticle1->GetT << 
263     G4cout << "nu2" << daughterparticle2->GetT << 
264     G4cout << "total" << (TT - parentmass) / k << 
265     if (GetVerboseLevel() > 2) {               << 
266       products->DumpInfo();                    << 
267     }                                          << 
268   }                                               239   }
269 #endif                                            240 #endif
270                                                << 
271   return products;                                241   return products;
272 }                                                 242 }
273                                                   243 
274 G4double G4MuonDecayChannelWithSpin::R_c(G4dou << 244 G4double G4MuonDecayChannelWithSpin::R_c(G4double x){
275 {                                              << 
276   auto n_max = (G4int)(100. * x);              << 
277                                                   245 
278   if (n_max < 10) n_max = 10;                  << 246   G4int n_max = (int)(100.*x);
                                                   >> 247 
                                                   >> 248   if(n_max<10)n_max=10;
279                                                   249 
280   G4double L2 = 0.0;                              250   G4double L2 = 0.0;
281                                                   251 
282   for (G4int n = 1; n <= n_max; ++n) {         << 252   for(G4int n=1; n<=n_max; n++){
283     L2 += std::pow(x, n) / (n * n);            << 253     L2 += std::pow(x,n)/(n*n);
284   }                                               254   }
285                                                   255 
                                                   >> 256   G4double omega = std::log(EMMU/EMASS);
                                                   >> 257 
286   G4double r_c;                                   258   G4double r_c;
287                                                   259 
288   r_c = 2. * L2 - (pi * pi / 3.) - 2.;         << 260   r_c = 2.*L2-(pi*pi/3.)-2.;
289   r_c = r_c + omega * (1.5 + 2. * std::log((1. << 261   r_c = r_c + omega * (1.5+2.*std::log((1.-x)/x));
290   r_c = r_c - std::log(x) * (2. * std::log(x)  << 262   r_c = r_c - std::log(x)*(2.*std::log(x)-1.);
291   r_c = r_c + (3. * std::log(x) - 1. - 1. / x) << 263   r_c = r_c + (3.*std::log(x)-1.-1./x)*std::log(1.-x);
292                                                   264 
293   return r_c;                                     265   return r_c;
294 }                                                 266 }
295                                                   267