Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4ANuElNucleusNcModel.cc
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26// $Id: G4ANuElNucleusNcModel.cc 91806 2015-08-06 12:20:45Z gcosmo $
27//
28// Geant4 Header : G4ANuElNucleusNcModel
29//
30// Author : V.Grichine 12.2.19
31//
32
35
36// #include "G4NuMuResQX.hh"
37
38#include "G4SystemOfUnits.hh"
39#include "G4ParticleTable.hh"
41#include "G4IonTable.hh"
42#include "Randomize.hh"
43#include "G4RandomDirection.hh"
44
45// #include "G4Integrator.hh"
46#include "G4DataVector.hh"
47#include "G4PhysicsTable.hh"
48#include "G4KineticTrack.hh"
51#include "G4Fragment.hh"
53
54
55#include "G4NeutrinoE.hh"
56// #include "G4AntiNeutrinoMu.hh"
57#include "G4Nucleus.hh"
58#include "G4LorentzVector.hh"
59
60using namespace std;
61using namespace CLHEP;
62
63#ifdef G4MULTITHREADED
64 G4Mutex G4ANuElNucleusNcModel::numuNucleusModel = G4MUTEX_INITIALIZER;
65#endif
66
67
70{
71 SetMinEnergy( 0.0*GeV );
72 SetMaxEnergy( 100.*TeV );
73 SetMinEnergy(1.e-6*eV);
74
75 theNuE = G4NeutrinoE::NeutrinoE();
76
77 fMnumu = 0.;
78 fData = fMaster = false;
80
81}
82
83
85{}
86
87
88void G4ANuElNucleusNcModel::ModelDescription(std::ostream& outFile) const
89{
90
91 outFile << "G4ANuElNucleusNcModel is a neutrino-nucleus (neutral current) scattering\n"
92 << "model which uses the standard model \n"
93 << "transfer parameterization. The model is fully relativistic\n";
94
95}
96
97/////////////////////////////////////////////////////////
98//
99// Read data from G4PARTICLEXSDATA (locally PARTICLEXSDATA)
100
102{
103 G4String pName = "anti_nu_e";
104
105 G4int nSize(0), i(0), j(0), k(0);
106
107 if(!fData)
108 {
109#ifdef G4MULTITHREADED
110 G4MUTEXLOCK(&numuNucleusModel);
111 if(!fData)
112 {
113#endif
114 fMaster = true;
115#ifdef G4MULTITHREADED
116 }
117 G4MUTEXUNLOCK(&numuNucleusModel);
118#endif
119 }
120
121 if(fMaster)
122 {
123 const char* path = G4FindDataDir("G4PARTICLEXSDATA");
124 std::ostringstream ost1, ost2, ost3, ost4;
125 ost1 << path << "/" << "neutrino" << "/" << pName << "/xarraynckr";
126
127 std::ifstream filein1( ost1.str().c_str() );
128
129 // filein.open("$PARTICLEXSDATA/");
130
131 filein1>>nSize;
132
133 for( k = 0; k < fNbin; ++k )
134 {
135 for( i = 0; i <= fNbin; ++i )
136 {
137 filein1 >> fNuMuXarrayKR[k][i];
138 // G4cout<< fNuMuXarrayKR[k][i] << " ";
139 }
140 }
141 // G4cout<<G4endl<<G4endl;
142
143 ost2 << path << "/" << "neutrino" << "/" << pName << "/xdistrnckr";
144 std::ifstream filein2( ost2.str().c_str() );
145
146 filein2>>nSize;
147
148 for( k = 0; k < fNbin; ++k )
149 {
150 for( i = 0; i < fNbin; ++i )
151 {
152 filein2 >> fNuMuXdistrKR[k][i];
153 // G4cout<< fNuMuXdistrKR[k][i] << " ";
154 }
155 }
156 // G4cout<<G4endl<<G4endl;
157
158 ost3 << path << "/" << "neutrino" << "/" << pName << "/q2arraynckr";
159 std::ifstream filein3( ost3.str().c_str() );
160
161 filein3>>nSize;
162
163 for( k = 0; k < fNbin; ++k )
164 {
165 for( i = 0; i <= fNbin; ++i )
166 {
167 for( j = 0; j <= fNbin; ++j )
168 {
169 filein3 >> fNuMuQarrayKR[k][i][j];
170 // G4cout<< fNuMuQarrayKR[k][i][j] << " ";
171 }
172 }
173 }
174 // G4cout<<G4endl<<G4endl;
175
176 ost4 << path << "/" << "neutrino" << "/" << pName << "/q2distrnckr";
177 std::ifstream filein4( ost4.str().c_str() );
178
179 filein4>>nSize;
180
181 for( k = 0; k < fNbin; ++k )
182 {
183 for( i = 0; i <= fNbin; ++i )
184 {
185 for( j = 0; j < fNbin; ++j )
186 {
187 filein4 >> fNuMuQdistrKR[k][i][j];
188 // G4cout<< fNuMuQdistrKR[k][i][j] << " ";
189 }
190 }
191 }
192 fData = true;
193 }
194}
195
196/////////////////////////////////////////////////////////
197
199 G4Nucleus & )
200{
201 G4bool result = false;
202 G4String pName = aPart.GetDefinition()->GetParticleName();
203 G4double energy = aPart.GetTotalEnergy();
205
206 if( pName == "anti_nu_e"
207 &&
208 energy > fMinNuEnergy )
209 {
210 result = true;
211 }
212
213 return result;
214}
215
216/////////////////////////////////////////// ClusterDecay ////////////////////////////////////////////////////////////
217//
218//
219
221 const G4HadProjectile& aTrack, G4Nucleus& targetNucleus)
222{
224 fProton = f2p2h = fBreak = false;
225 const G4HadProjectile* aParticle = &aTrack;
226 G4double energy = aParticle->GetTotalEnergy();
227
228 G4String pName = aParticle->GetDefinition()->GetParticleName();
229
230 if( energy < fMinNuEnergy )
231 {
234 return &theParticleChange;
235 }
236 SampleLVkr( aTrack, targetNucleus);
237
238 if( fBreak == true || fEmu < fMnumu ) // ~5*10^-6
239 {
240 // G4cout<<"ni, ";
243 return &theParticleChange;
244 }
245
246 // LVs of initial state
247
248 G4LorentzVector lvp1 = aParticle->Get4Momentum();
249 G4LorentzVector lvt1( 0., 0., 0., fM1 );
251
252 // 1-pi by fQtransfer && nu-energy
253 G4LorentzVector lvpip1( 0., 0., 0., mPip );
254 G4LorentzVector lvsum, lv2, lvX;
255 G4ThreeVector eP;
256 G4double cost(1.), sint(0.), phi(0.), muMom(0.), massX2(0.);
257 G4DynamicParticle* aLept = nullptr; // lepton lv
258
259 G4int Z = targetNucleus.GetZ_asInt();
260 G4int A = targetNucleus.GetA_asInt();
261 G4double mTarg = targetNucleus.AtomicMass(A,Z);
262 G4int pdgP(0), qB(0);
263 // G4double mSum = G4ParticleTable::GetParticleTable()->FindParticle(2212)->GetPDGMass() + mPip;
264
265 G4int iPi = GetOnePionIndex(energy);
266 G4double p1pi = GetNuMuOnePionProb( iPi, energy);
267
268 if( p1pi > G4UniformRand() && fCosTheta > 0.9 ) // && fQtransfer < 0.95*GeV ) // mu- & coherent pion + nucleus
269 {
270 // lvsum = lvp1 + lvpip1;
271 lvsum = lvp1 + lvt1;
272 // cost = fCosThetaPi;
273 cost = fCosTheta;
274 sint = std::sqrt( (1.0 - cost)*(1.0 + cost) );
275 phi = G4UniformRand()*CLHEP::twopi;
276 eP = G4ThreeVector( sint*std::cos(phi), sint*std::sin(phi), cost );
277
278 // muMom = sqrt(fEmuPi*fEmuPi-fMnumu*fMnumu);
279 muMom = sqrt(fEmu*fEmu-fMnumu*fMnumu);
280
281 eP *= muMom;
282
283 // lv2 = G4LorentzVector( eP, fEmuPi );
284 lv2 = G4LorentzVector( eP, fEmu );
285 lv2 = fLVl;
286
287 lvX = lvsum - lv2;
288 lvX = fLVh;
289 massX2 = lvX.m2();
290 G4double massX = lvX.m();
291 G4double massR = fLVt.m();
292
293 // if ( massX2 <= 0. ) // vmg: very rarely ~ (1-4)e-6 due to big Q2/x, to be improved
294 if ( massX2 <= fM1*fM1 ) // 9-3-20 vmg: very rarely ~ (1-4)e-6 due to big Q2/x, to be improved
295 if ( lvX.e() <= fM1 ) // 9-3-20 vmg: very rarely ~ (1-4)e-6 due to big Q2/x, to be improved
296 {
299 return &theParticleChange;
300 }
301 fW2 = massX2;
302
303 if( pName == "anti_nu_e" ) aLept = new G4DynamicParticle( theNuE, lv2 );
304 // else if( pName == "anti_nu_mu") aLept = new G4DynamicParticle( theANuMu, lv2 );
305 else
306 {
309 return &theParticleChange;
310 }
311
312 pdgP = 111;
313
314 G4double eCut; // = fMpi + 0.5*(fMpi*fMpi - massX2)/mTarg; // massX -> fMpi
315
316 if( A > 1 )
317 {
318 eCut = (fMpi + mTarg)*(fMpi + mTarg) - (massX + massR)*(massX + massR);
319 eCut /= 2.*massR;
320 eCut += massX;
321 }
322 else eCut = fM1 + fMpi;
323
324 if ( lvX.e() > eCut ) // && sqrt( GetW2() ) < 1.4*GeV ) //
325 {
326 CoherentPion( lvX, pdgP, targetNucleus);
327 }
328 else
329 {
332 return &theParticleChange;
333 }
335
336 return &theParticleChange;
337 }
338 else // lepton part in lab
339 {
340 lvsum = lvp1 + lvt1;
341 cost = fCosTheta;
342 sint = std::sqrt( (1.0 - cost)*(1.0 + cost) );
343 phi = G4UniformRand()*CLHEP::twopi;
344 eP = G4ThreeVector( sint*std::cos(phi), sint*std::sin(phi), cost );
345
346 muMom = sqrt(fEmu*fEmu-fMnumu*fMnumu);
347
348 eP *= muMom;
349
350 lv2 = G4LorentzVector( eP, fEmu );
351
352 lvX = lvsum - lv2;
353
354 massX2 = lvX.m2();
355
356 if ( massX2 <= 0. ) // vmg: very rarely ~ (1-4)e-6 due to big Q2/x, to be improved
357 {
360 return &theParticleChange;
361 }
362 fW2 = massX2;
363
364 aLept = new G4DynamicParticle( theNuE, lv2 );
365
367 }
368
369 // hadron part
370
371 fRecoil = nullptr;
372 fCascade = false;
373 fString = false;
374
375 if( A == 1 )
376 {
377 qB = 1;
378
379 // if( G4UniformRand() > 0.1 ) // > 0.9999 ) // > 0.0001 ) //
380 {
381 ClusterDecay( lvX, qB );
382 }
383 return &theParticleChange;
384 }
385 G4Nucleus recoil;
386 G4double rM(0.), ratio = G4double(Z)/G4double(A);
387
388 if( ratio > G4UniformRand() ) // proton is excited
389 {
390 fProton = true;
391 recoil = G4Nucleus(A-1,Z-1);
392 fRecoil = &recoil;
393 rM = recoil.AtomicMass(A-1,Z-1);
394
397 }
398 else // excited neutron
399 {
400 fProton = false;
401 recoil = G4Nucleus(A-1,Z);
402 fRecoil = &recoil;
403 rM = recoil.AtomicMass(A-1,Z);
404
407 }
408 // G4int index = GetEnergyIndex(energy);
409 G4int nepdg = aParticle->GetDefinition()->GetPDGEncoding();
410
411 G4double qeTotRat; // = GetNuMuQeTotRat(index, energy);
412 qeTotRat = CalculateQEratioA( Z, A, energy, nepdg);
413
414 G4ThreeVector dX = (lvX.vect()).unit();
415 G4double eX = lvX.e(); // excited nucleon
416 G4double mX = sqrt(massX2);
417
418 if( qeTotRat > G4UniformRand() || mX <= fMt ) // || eX <= 1232.*MeV) // QE
419 {
420 fString = false;
421
422 if( fProton )
423 {
424 fPDGencoding = 2212;
425 fMr = proton_mass_c2;
426 recoil = G4Nucleus(A-1,Z-1);
427 fRecoil = &recoil;
428 rM = recoil.AtomicMass(A-1,Z-1);
429 }
430 else
431 {
432 fPDGencoding = 2112;
434 FindParticle(fPDGencoding)->GetPDGMass(); // 939.5654133*MeV;
435 recoil = G4Nucleus(A-1,Z);
436 fRecoil = &recoil;
437 rM = recoil.AtomicMass(A-1,Z);
438 }
439 G4double eTh = fMr+0.5*(fMr*fMr-mX*mX)/rM;
440
441 if(eX <= eTh) // vmg, very rarely out of kinematics
442 {
445 return &theParticleChange;
446 }
447 FinalBarion( lvX, 0, fPDGencoding ); // p(n)+deexcited recoil
448 }
449 else // if ( eX < 9500000.*GeV ) // < 25.*GeV) // < 95.*GeV ) // < 2.5*GeV ) //cluster decay
450 {
451 if ( fProton && pName == "anti_nu_e" ) qB = 1;
452 else if( !fProton && pName == "anti_nu_e" ) qB = 0;
453
454 ClusterDecay( lvX, qB );
455 }
456 return &theParticleChange;
457}
458
459
460/////////////////////////////////////////////////////////////////////
461////////////////////////////////////////////////////////////////////
462///////////////////////////////////////////////////////////////////
463
464/////////////////////////////////////////////////
465//
466// sample x, then Q2
467
469{
470 fBreak = false;
471 G4int A = targetNucleus.GetA_asInt(), iTer(0), iTerMax(100);
472 G4int Z = targetNucleus.GetZ_asInt();
473 G4double e3(0.), pMu2(0.), pX2(0.), nMom(0.), rM(0.), hM(0.), tM = targetNucleus.AtomicMass(A,Z);
474 G4double cost(1.), sint(0.), phi(0.), muMom(0.);
475 G4ThreeVector eP, bst;
476 const G4HadProjectile* aParticle = &aTrack;
477 G4LorentzVector lvp1 = aParticle->Get4Momentum();
478 nMom = NucleonMomentum( targetNucleus );
479
480 if( A == 1 || nMom == 0. ) // hydrogen, no Fermi motion ???
481 {
482 fNuEnergy = aParticle->GetTotalEnergy();
483 iTer = 0;
484
485 do
486 {
490
491 if( fXsample > 0. )
492 {
493 fW2 = fM1*fM1 - fQ2 + fQ2/fXsample; // sample excited hadron mass
495 }
496 else
497 {
498 fW2 = fM1*fM1;
499 fEmu = fNuEnergy;
500 }
501 e3 = fNuEnergy + fM1 - fEmu;
502
503 // if( e3 < sqrt(fW2) ) G4cout<<"energyX = "<<e3/GeV<<", fW = "<<sqrt(fW2)/GeV<<G4endl; // vmg ~10^-5 for NC
504
505 pMu2 = fEmu*fEmu - fMnumu*fMnumu;
506 pX2 = e3*e3 - fW2;
507
508 fCosTheta = fNuEnergy*fNuEnergy + pMu2 - pX2;
509 fCosTheta /= 2.*fNuEnergy*sqrt(pMu2);
510 iTer++;
511 }
512 while( ( abs(fCosTheta) > 1. || fEmu < fMnumu ) && iTer < iTerMax );
513
514 if( iTer >= iTerMax ) { fBreak = true; return; }
515
516 if( abs(fCosTheta) > 1.) // vmg: due to big Q2/x values. To be improved ...
517 {
518 G4cout<<"H2: fCosTheta = "<<fCosTheta<<", fEmu = "<<fEmu<<G4endl;
519 // fCosTheta = -1. + 2.*G4UniformRand();
520 if(fCosTheta < -1.) fCosTheta = -1.;
521 if(fCosTheta > 1.) fCosTheta = 1.;
522 }
523 // LVs
524
525 G4LorentzVector lvt1 = G4LorentzVector( 0., 0., 0., fM1 );
526 G4LorentzVector lvsum = lvp1 + lvt1;
527
528 cost = fCosTheta;
529 sint = std::sqrt( (1.0 - cost)*(1.0 + cost) );
530 phi = G4UniformRand()*CLHEP::twopi;
531 eP = G4ThreeVector( sint*std::cos(phi), sint*std::sin(phi), cost );
532 muMom = sqrt(fEmu*fEmu-fMnumu*fMnumu);
533 eP *= muMom;
534 fLVl = G4LorentzVector( eP, fEmu );
535
536 fLVh = lvsum - fLVl;
537 fLVt = G4LorentzVector( 0., 0., 0., 0. ); // no recoil
538 }
539 else // Fermi motion, Q2 in nucleon rest frame
540 {
541 G4ThreeVector nMomDir = nMom*G4RandomDirection();
542
543 if( !f2p2h ) // 1p1h
544 {
545 G4Nucleus recoil(A-1,Z);
546 rM = sqrt( recoil.AtomicMass(A-1,Z)*recoil.AtomicMass(A-1,Z) + nMom*nMom );
547 hM = tM - rM;
548
549 fLVt = G4LorentzVector( nMomDir, sqrt( rM*rM+nMom*nMom ) );
550 fLVh = G4LorentzVector(-nMomDir, sqrt( hM*hM+nMom*nMom ) );
551 }
552 else // 2p2h
553 {
554 G4Nucleus recoil(A-2,Z-1);
555 rM = recoil.AtomicMass(A-2,Z-1)+sqrt(nMom*nMom+fM1*fM1);
556 hM = tM - rM;
557
558 fLVt = G4LorentzVector( nMomDir, sqrt( rM*rM+nMom*nMom ) );
559 fLVh = G4LorentzVector(-nMomDir, sqrt( hM*hM+nMom*nMom ) );
560 }
561 // G4cout<<hM<<", ";
562 // bst = fLVh.boostVector(); // 9-3-20
563
564 // lvp1.boost(-bst); // 9-3-20 -> nucleon rest system, where Q2 transfer is ???
565
566 fNuEnergy = lvp1.e();
567 iTer = 0;
568
569 do
570 {
574
575 if( fXsample > 0. )
576 {
577 fW2 = fM1*fM1 - fQ2 + fQ2/fXsample; // sample excited hadron mass
579 }
580 else
581 {
582 fW2 = fM1*fM1;
583 fEmu = fNuEnergy;
584 }
585
586 // if(fEmu < 0.) G4cout<<"fEmu = "<<fEmu<<" hM = "<<hM<<G4endl;
587
588 e3 = fNuEnergy + fM1 - fEmu;
589
590 // if( e3 < sqrt(fW2) ) G4cout<<"energyX = "<<e3/GeV<<", fW = "<<sqrt(fW2)/GeV<<G4endl;
591
592 pMu2 = fEmu*fEmu - fMnumu*fMnumu;
593 pX2 = e3*e3 - fW2;
594
595 fCosTheta = fNuEnergy*fNuEnergy + pMu2 - pX2;
596 fCosTheta /= 2.*fNuEnergy*sqrt(pMu2);
597 iTer++;
598 }
599 while( ( abs(fCosTheta) > 1. || fEmu < fMnumu ) && iTer < iTerMax );
600
601 if( iTer >= iTerMax ) { fBreak = true; return; }
602
603 if( abs(fCosTheta) > 1.) // vmg: due to big Q2/x values. To be improved ...
604 {
605 G4cout<<"FM: fCosTheta = "<<fCosTheta<<", fEmu = "<<fEmu<<G4endl;
606 // fCosTheta = -1. + 2.*G4UniformRand();
607 if(fCosTheta < -1.) fCosTheta = -1.;
608 if(fCosTheta > 1.) fCosTheta = 1.;
609 }
610 // LVs
611 G4LorentzVector lvt1 = G4LorentzVector( 0., 0., 0., fM1 );
612 G4LorentzVector lvsum = lvp1 + lvt1;
613
614 cost = fCosTheta;
615 sint = std::sqrt( (1.0 - cost)*(1.0 + cost) );
616 phi = G4UniformRand()*CLHEP::twopi;
617 eP = G4ThreeVector( sint*std::cos(phi), sint*std::sin(phi), cost );
618 muMom = sqrt(fEmu*fEmu-fMnumu*fMnumu);
619 eP *= muMom;
620 fLVl = G4LorentzVector( eP, fEmu );
621 fLVh = lvsum - fLVl;
622 // back to lab system
623 // fLVl.boost(bst); // 9-3-20
624 // fLVh.boost(bst); // 9-3-20
625 }
626 //G4cout<<iTer<<", "<<fBreak<<"; ";
627}
628
629//
630//
631///////////////////////////
const char * G4FindDataDir(const char *)
CLHEP::HepLorentzVector G4LorentzVector
G4ThreeVector G4RandomDirection()
#define G4MUTEX_INITIALIZER
Definition: G4Threading.hh:85
#define G4MUTEXLOCK(mutex)
Definition: G4Threading.hh:251
#define G4MUTEXUNLOCK(mutex)
Definition: G4Threading.hh:254
std::mutex G4Mutex
Definition: G4Threading.hh:81
CLHEP::Hep3Vector G4ThreeVector
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
const G4int Z[17]
const G4double A[17]
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
#define G4UniformRand()
Definition: Randomize.hh:52
Hep3Vector unit() const
Hep3Vector vect() const
G4ANuElNucleusNcModel(const G4String &name="ANuElNuclNcModel")
void SampleLVkr(const G4HadProjectile &aTrack, G4Nucleus &targetNucleus)
virtual void ModelDescription(std::ostream &) const
virtual G4bool IsApplicable(const G4HadProjectile &aTrack, G4Nucleus &targetNucleus)
virtual G4HadFinalState * ApplyYourself(const G4HadProjectile &aTrack, G4Nucleus &targetNucleus)
void AddSecondary(G4DynamicParticle *aP, G4int mod=-1)
void SetEnergyChange(G4double anEnergy)
void SetMomentumChange(const G4ThreeVector &aV)
const G4ParticleDefinition * GetDefinition() const
const G4LorentzVector & Get4Momentum() const
G4double GetTotalEnergy() const
void SetMinEnergy(G4double anEnergy)
void SetMaxEnergy(const G4double anEnergy)
static G4NeutrinoE * NeutrinoE()
Definition: G4NeutrinoE.cc:84
void CoherentPion(G4LorentzVector &lvP, G4int pdgP, G4Nucleus &targetNucleus)
static G4double fNuMuQarrayKR[50][51][51]
static G4double fNuMuXarrayKR[50][51]
G4double NucleonMomentum(G4Nucleus &targetNucleus)
G4int GetOnePionIndex(G4double energy)
G4double SampleXkr(G4double energy)
G4double SampleQkr(G4double energy, G4double xx)
G4double GetNuMuOnePionProb(G4int index, G4double energy)
static G4double fNuMuXdistrKR[50][50]
static G4double fNuMuQdistrKR[50][51][50]
G4double CalculateQEratioA(G4int Z, G4int A, G4double energy, G4int nepdg)
void ClusterDecay(G4LorentzVector &lvX, G4int qX)
void FinalBarion(G4LorentzVector &lvB, G4int qB, G4int pdgB)
G4int GetA_asInt() const
Definition: G4Nucleus.hh:99
G4int GetZ_asInt() const
Definition: G4Nucleus.hh:105
G4double AtomicMass(const G4double A, const G4double Z, const G4int numberOfLambdas=0) const
Definition: G4Nucleus.cc:357
const G4String & GetParticleName() const
G4ParticleDefinition * FindParticle(G4int PDGEncoding)
static G4ParticleTable * GetParticleTable()
Definition: DoubConv.h:17