Geant4 11.1.1
Toolkit for the simulation of the passage of particles through matter
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G4ParticleHPInelasticBaseFS Class Referenceabstract

#include <G4ParticleHPInelasticBaseFS.hh>

+ Inheritance diagram for G4ParticleHPInelasticBaseFS:

Public Member Functions

 G4ParticleHPInelasticBaseFS ()
 
virtual ~G4ParticleHPInelasticBaseFS ()
 
void Init (G4double A, G4double Z, G4int M, G4String &dirName, G4String &bit, G4ParticleDefinition *)
 
void BaseApply (const G4HadProjectile &theTrack, G4ParticleDefinition **theDefs, G4int nDef)
 
void InitGammas (G4double AR, G4double ZR)
 
virtual G4HadFinalStateApplyYourself (const G4HadProjectile &theTrack)=0
 
virtual G4ParticleHPFinalStateNew ()=0
 
virtual G4double GetXsec (G4double anEnergy)
 
virtual G4ParticleHPVectorGetXsec ()
 
- Public Member Functions inherited from G4ParticleHPFinalState
 G4ParticleHPFinalState ()
 
virtual ~G4ParticleHPFinalState ()
 
void Init (G4double A, G4double Z, G4String &dirName, G4String &aFSType, G4ParticleDefinition *projectile)
 
virtual void Init (G4double A, G4double Z, G4int M, G4String &dirName, G4String &aFSType, G4ParticleDefinition *)=0
 
virtual G4HadFinalStateApplyYourself (const G4HadProjectile &)
 
virtual G4ParticleHPFinalStateNew ()=0
 
G4bool HasXsec ()
 
G4bool HasFSData ()
 
G4bool HasAnyData ()
 
virtual G4double GetXsec (G4double)
 
virtual G4ParticleHPVectorGetXsec ()
 
void SetA_Z (G4double anA, G4double aZ, G4int aM=0)
 
G4double GetZ ()
 
G4double GetN ()
 
G4double GetA ()
 
G4int GetM ()
 
void SetAZMs (G4double anA, G4double aZ, G4int aM, G4ParticleHPDataUsed used)
 
void SetProjectile (G4ParticleDefinition *projectile)
 

Protected Attributes

G4ParticleHPVectortheXsection
 
G4ParticleHPEnergyDistributiontheEnergyDistribution
 
G4ParticleHPAngulartheAngularDistribution
 
G4ParticleHPEnAngCorrelationtheEnergyAngData
 
G4ParticleHPPhotonDisttheFinalStatePhotons
 
G4double theNuclearMassDifference
 
G4ParticleHPDeExGammas theGammas
 
G4String gammaPath
 
G4double Qvalue
 
- Protected Attributes inherited from G4ParticleHPFinalState
G4bool hasXsec
 
G4bool hasFSData
 
G4bool hasAnyData
 
G4ParticleHPNames theNames
 
G4Cache< G4HadFinalState * > theResult
 
G4ParticleDefinitiontheProjectile
 
G4double theBaseA
 
G4double theBaseZ
 
G4int theBaseM
 
G4int theNDLDataZ
 
G4int theNDLDataA
 
G4int theNDLDataM
 
G4int secID
 

Additional Inherited Members

- Protected Member Functions inherited from G4ParticleHPFinalState
void adjust_final_state (G4LorentzVector)
 

Detailed Description

Definition at line 43 of file G4ParticleHPInelasticBaseFS.hh.

Constructor & Destructor Documentation

◆ G4ParticleHPInelasticBaseFS()

G4ParticleHPInelasticBaseFS::G4ParticleHPInelasticBaseFS ( )
inline

◆ ~G4ParticleHPInelasticBaseFS()

virtual G4ParticleHPInelasticBaseFS::~G4ParticleHPInelasticBaseFS ( )
inlinevirtual

Definition at line 61 of file G4ParticleHPInelasticBaseFS.hh.

62 {
63 delete theXsection;
66 if (theEnergyAngData != 0) delete theEnergyAngData;
68 }

Member Function Documentation

◆ ApplyYourself()

◆ BaseApply()

void G4ParticleHPInelasticBaseFS::BaseApply ( const G4HadProjectile theTrack,
G4ParticleDefinition **  theDefs,
G4int  nDef 
)

Definition at line 170 of file G4ParticleHPInelasticBaseFS.cc.

173{
174 // prepare neutron
175 if ( theResult.Get() == NULL ) theResult.Put( new G4HadFinalState );
176 theResult.Get()->Clear();
177 G4double eKinetic = theTrack.GetKineticEnergy();
178 const G4HadProjectile *hadProjectile = &theTrack;
179 G4ReactionProduct incidReactionProduct( const_cast<G4ParticleDefinition *>(hadProjectile->GetDefinition()) );
180 incidReactionProduct.SetMomentum( hadProjectile->Get4Momentum().vect() );
181 incidReactionProduct.SetKineticEnergy( eKinetic );
182
183 // prepare target
184 G4double targetMass;
185 G4double eps = 0.0001;
186 targetMass = ( G4NucleiProperties::GetNuclearMass(static_cast<G4int>(theBaseA+eps), static_cast<G4int>(theBaseZ+eps))) /
187 //theProjectile->GetPDGMass();
189
190 // give priority to ENDF vales for target mass
191 if(theEnergyAngData!=0)
192 { targetMass = theEnergyAngData->GetTargetMass(); }
194 { targetMass = theAngularDistribution->GetTargetMass(); }
195
196 // 110512 TKDB ENDF-VII.0 21Sc45 has trouble in MF4MT22 (n,np) targetMass is not properly recorded.
197 if ( targetMass == 0 )
198 {
199 //G4cout << "TKDB targetMass = 0; ENDF-VII.0 21Sc45 has trouble in MF4MT22 (n,np) targetMass is not properly recorded. This could be a similar situation." << G4endl;
200 //targetMass = ( G4NucleiProperties::GetNuclearMass(static_cast<G4int>(theBaseA+eps), static_cast<G4int>(theBaseZ+eps))) / theProjectile->GetPDGMass();
201 targetMass = ( G4NucleiProperties::GetNuclearMass(static_cast<G4int>(theBaseA+eps), static_cast<G4int>(theBaseZ+eps))) / G4Neutron::Neutron()->GetPDGMass();
202 }
203
204 G4Nucleus aNucleus;
205 G4ReactionProduct theTarget;
206
207 G4ThreeVector neuVelo = (1./G4Neutron::Neutron()->GetPDGMass())*incidReactionProduct.GetMomentum();
208 theTarget = aNucleus.GetBiasedThermalNucleus( targetMass, neuVelo, theTrack.GetMaterial()->GetTemperature());
209
211
212 // prepare energy in target rest frame
213 G4ReactionProduct boosted;
214 boosted.Lorentz(incidReactionProduct, theTarget);
215 eKinetic = boosted.GetKineticEnergy();
216 G4double orgMomentum = boosted.GetMomentum().mag();
217
218 // Take N-body phase-space distribution, if no other data present.
219 if(!HasFSData()) // adding the residual is trivial here @@@
220 {
221 G4ParticleHPNBodyPhaseSpace thePhaseSpaceDistribution;
222 G4double aPhaseMass=0;
223 G4int ii;
224 for(ii=0; ii<nDef; ++ii)
225 {
226 aPhaseMass+=theDefs[ii]->GetPDGMass();
227 }
228
229 //----------------------------------------------------------------------------
230 if(Qvalue<1.*CLHEP::keV && Qvalue>-1.*CLHEP::keV) {
231 // Not in the G4NDL lib or not calculated yet:
232
233 // Calculate residual:
234 G4int ResidualA=theBaseA;
235 G4int ResidualZ=theBaseZ;
236 for (ii = 0; ii < nDef; ++ii) {
237 ResidualZ -= theDefs[ii]->GetAtomicNumber();
238 ResidualA -= theDefs[ii]->GetBaryonNumber();
239 }
240
241 if (ResidualA > 0 && ResidualZ > 0) {
242 G4ParticleDefinition* resid = G4IonTable::GetIonTable()->GetIon(ResidualZ,ResidualA);
243 Qvalue = incidReactionProduct.GetMass()+theTarget.GetMass()-aPhaseMass-resid->GetPDGMass();
244 }
245
246 if (Qvalue > 400*CLHEP::MeV || Qvalue < -400*CLHEP::MeV) {
247 //Then Q value is probably too large ...
248 Qvalue = 1.1*CLHEP::keV;
249 }
250 }
251 //----------------------------------------------------------------------------
252
253 thePhaseSpaceDistribution.Init(aPhaseMass, nDef);
254 thePhaseSpaceDistribution.SetProjectileRP(&incidReactionProduct);
255 thePhaseSpaceDistribution.SetTarget(&theTarget);
256 thePhaseSpaceDistribution.SetQValue(Qvalue);
257
258 for(ii=0; ii<nDef; ++ii)
259 {
260 G4double massCode = 1000.*std::abs(theDefs[ii]->GetPDGCharge());
261 massCode += theDefs[ii]->GetBaryonNumber();
262 G4double dummy = 0;
263 G4ReactionProduct * aSec = thePhaseSpaceDistribution.Sample(eKinetic, massCode, dummy);
264 aSec->Lorentz(*aSec, -1.*theTarget);
265 G4DynamicParticle * aPart = new G4DynamicParticle();
266 aPart->SetDefinition(aSec->GetDefinition());
267 aPart->SetMomentum(aSec->GetMomentum());
268 delete aSec;
269 theResult.Get()->AddSecondary(aPart, secID);
270#ifdef G4PHPDEBUG
271 if( std::getenv("G4ParticleHPDebug"))
272 G4cout << this
273 << " G4ParticleHPInelasticBaseFS::BaseApply NoFSData add secondary "
275 << " E= " << aPart->GetKineticEnergy() << " NSECO "
277#endif
278 }
280 // Final momentum check should be done before return
282 G4LorentzVector targ_4p_lab ( theTarget.GetMomentum() , std::sqrt( targ_pd->GetPDGMass()*targ_pd->GetPDGMass() + theTarget.GetMomentum().mag2() ) );
283 G4LorentzVector proj_4p_lab = theTrack.Get4Momentum();
284 G4LorentzVector init_4p_lab = proj_4p_lab + targ_4p_lab;
285 adjust_final_state ( init_4p_lab );
286
287 return;
288 }
289
290 // set target and neutron in the relevant exit channel
292 {
294 theAngularDistribution->SetProjectileRP(incidReactionProduct);
295 }
296 else if(theEnergyAngData!=0)
297 {
298 theEnergyAngData->SetTarget(theTarget);
299 theEnergyAngData->SetProjectileRP(incidReactionProduct);
300 }
301
302 G4ReactionProductVector * tmpHadrons = 0;
303#ifdef G4PHPDEBUG
304 //To avoid compilation error around line 532.
305 G4int ii(0);
306#endif
307 G4int dummy;
308 std::size_t i;
309
310 if(theEnergyAngData != 0)
311 {
312 tmpHadrons = theEnergyAngData->Sample(eKinetic);
313
314 if ( ! G4ParticleHPManager::GetInstance()->GetDoNotAdjustFinalState() ) {
315 // Adjust A and Z in the case of miss much between selected data and target nucleus
316 if ( tmpHadrons != nullptr ) {
317 G4int sumA = 0;
318 G4int sumZ = 0;
319 G4int maxA = 0;
320 G4int jAtMaxA = 0;
321 for ( G4int j = 0 ; j != (G4int)tmpHadrons->size() ; ++j ) {
322 //G4cout << __FILE__ << " " << __LINE__ << "th line: tmpHadrons->at(j)->GetDefinition()->GetParticleName() = " << tmpHadrons->at(j)->GetDefinition()->GetParticleName() << G4endl;
323 if ( tmpHadrons->at(j)->GetDefinition()->GetBaryonNumber() > maxA ) {
324 maxA = tmpHadrons->at(j)->GetDefinition()->GetBaryonNumber();
325 jAtMaxA = j;
326 }
327 sumA += tmpHadrons->at(j)->GetDefinition()->GetBaryonNumber();
328 sumZ += G4int( tmpHadrons->at(j)->GetDefinition()->GetPDGCharge() + eps );
329 }
330 G4int dA = (G4int)theBaseA + hadProjectile->GetDefinition()->GetBaryonNumber() - sumA;
331 G4int dZ = (G4int)theBaseZ + G4int( hadProjectile->GetDefinition()->GetPDGCharge() + eps ) - sumZ;
332 if ( dA < 0 || dZ < 0 ) {
333 G4int newA = tmpHadrons->at(jAtMaxA)->GetDefinition()->GetBaryonNumber() + dA ;
334 G4int newZ = G4int( tmpHadrons->at(jAtMaxA)->GetDefinition()->GetPDGCharge() + eps ) + dZ;
335 if(newA>newZ && newZ>0){
336 G4ParticleDefinition* pd = G4IonTable::GetIonTable()->GetIon ( newZ , newA );
337 tmpHadrons->at( jAtMaxA )->SetDefinition( pd );
338 }
339 }
340 }
341 }
342 }
343 else if(theAngularDistribution!= 0)
344 {
345 G4bool * Done = new G4bool[nDef];
346 G4int i0;
347 for(i0=0; i0<nDef; ++i0) Done[i0] = false;
348
349 tmpHadrons = new G4ReactionProductVector;
350 G4ReactionProduct * aHadron;
351 G4double localMass = ( G4NucleiProperties::GetNuclearMass(static_cast<G4int>(theBaseA+eps), static_cast<G4int>(theBaseZ+eps)));
352 G4ThreeVector bufferedDirection(0,0,0);
353 for(i0=0; i0<nDef; ++i0)
354 {
355 if(!Done[i0])
356 {
357 aHadron = new G4ReactionProduct;
359 {
360 aHadron->SetDefinition(theDefs[i0]);
361 aHadron->SetKineticEnergy(theEnergyDistribution->Sample(eKinetic, dummy));
362 }
363 else if(nDef == 1)
364 {
365 aHadron->SetDefinition(theDefs[i0]);
366 aHadron->SetKineticEnergy(eKinetic);
367 }
368 else if(nDef == 2)
369 {
370 aHadron->SetDefinition(theDefs[i0]);
371 aHadron->SetKineticEnergy(50*CLHEP::MeV);
372 }
373 else
374 {
375 throw G4HadronicException(__FILE__, __LINE__, "No energy distribution to sample from in InelasticBaseFS::BaseApply");
376 }
378 if(theEnergyDistribution==0 && nDef == 2)
379 {
380 if(i0==0)
381 {
382 G4double mass1 = theDefs[0]->GetPDGMass();
383 G4double mass2 = theDefs[1]->GetPDGMass();
385 G4int z1 = static_cast<G4int>(theBaseZ+eps-theDefs[0]->GetPDGCharge()-theDefs[1]->GetPDGCharge());
386 G4int a1 = static_cast<G4int>(theBaseA+eps)-theDefs[0]->GetBaryonNumber()-theDefs[1]->GetBaryonNumber();
387 G4double concreteMass = G4NucleiProperties::GetNuclearMass(a1, z1);
388 G4double availableEnergy = eKinetic+massn+localMass-mass1-mass2-concreteMass;
389 // available kinetic energy in CMS (non relativistic)
390 G4double emin = availableEnergy+mass1+mass2 - std::sqrt((mass1+mass2)*(mass1+mass2)+orgMomentum*orgMomentum);
391 G4double p1=std::sqrt(2.*mass2*emin);
392 bufferedDirection = p1*aHadron->GetMomentum().unit();
393#ifdef G4PHPDEBUG
394 if(std::getenv("G4ParticleHPDebug")) // @@@@@ verify the nucleon counting...
395 {
396 G4cout << "G4ParticleHPInelasticBaseFS "<<z1<<" "<<theBaseZ<<" "<<a1<<" "<<theBaseA<<" "<<availableEnergy<<" "
397 << emin<<G4endl;
398 }
399#endif
400 }
401 else
402 {
403 bufferedDirection = -bufferedDirection;
404 }
405 // boost from cms to lab
406#ifdef G4PHPDEBUG
407 if(std::getenv("G4ParticleHPDebug"))
408 {
409 G4cout << " G4ParticleHPInelasticBaseFS "<<bufferedDirection.mag2()<<G4endl;
410 }
411#endif
412 aHadron->SetTotalEnergy( std::sqrt(aHadron->GetMass()*aHadron->GetMass()
413 +bufferedDirection.mag2()) );
414 aHadron->SetMomentum(bufferedDirection);
415 aHadron->Lorentz(*aHadron, -1.*(theTarget+incidReactionProduct));
416#ifdef G4PHPDEBUG
417 if(std::getenv("G4ParticleHPDebug"))
418 {
419 G4cout << " G4ParticleHPInelasticBaseFS "<<aHadron->GetTotalEnergy()<<" "<<aHadron->GetMomentum()<<G4endl;
420 }
421#endif
422 }
423 tmpHadrons->push_back(aHadron);
424#ifdef G4PHPDEBUG
425 if( std::getenv("G4ParticleHPDebug")) G4cout << " G4ParticleHPInelasticBaseFS::BaseApply FSData add secondary " << aHadron->GetDefinition()->GetParticleName() << " E= " << aHadron->GetKineticEnergy() << G4endl;
426#endif
427 }
428 }
429 delete [] Done;
430 }
431 else
432 {
433 throw G4HadronicException(__FILE__, __LINE__, "No data to create the neutrons in NInelasticFS");
434 }
435
436 G4ReactionProductVector * thePhotons = nullptr;
438 {
439 // the photon distributions are in the Nucleus rest frame.
440 G4ReactionProduct boosted_tmp;
441 boosted_tmp.Lorentz(incidReactionProduct, theTarget);
442 G4double anEnergy = boosted_tmp.GetKineticEnergy();
443 thePhotons = theFinalStatePhotons->GetPhotons(anEnergy);
444 if(thePhotons!=0)
445 {
446 for(i=0; i<thePhotons->size(); ++i)
447 {
448 // back to lab
449 thePhotons->operator[](i)->Lorentz(*(thePhotons->operator[](i)), -1.*theTarget);
450 }
451 }
452 }
453 else if(theEnergyAngData!=0)
454 {
455
456 // PA130927: do not create photons to adjust binding energy
457 G4bool bAdjustPhotons = true;
458#ifdef PHP_AS_HP
459 bAdjustPhotons = true;
460#else
462 bAdjustPhotons = false;
463#endif
464
465 if( bAdjustPhotons ) {
466 G4double theGammaEnergy = theEnergyAngData->GetTotalMeanEnergy();
467 G4double anEnergy = boosted.GetKineticEnergy();
468 theGammaEnergy = anEnergy-theGammaEnergy;
469 theGammaEnergy += theNuclearMassDifference;
470 G4double eBindProducts = 0;
471 G4double eBindN = 0;
472 G4double eBindP = 0;
477 G4int ia=0;
478 for(i=0; i<tmpHadrons->size(); i++)
479 {
480 if(tmpHadrons->operator[](i)->GetDefinition() == G4Neutron::Neutron())
481 {
482 eBindProducts+=eBindN;
483 }
484 else if(tmpHadrons->operator[](i)->GetDefinition() == G4Proton::Proton())
485 {
486 eBindProducts+=eBindP;
487 }
488 else if(tmpHadrons->operator[](i)->GetDefinition() == G4Deuteron::Deuteron())
489 {
490 eBindProducts+=eBindD;
491 }
492 else if(tmpHadrons->operator[](i)->GetDefinition() == G4Triton::Triton())
493 {
494 eBindProducts+=eBindT;
495 }
496 else if(tmpHadrons->operator[](i)->GetDefinition() == G4He3::He3())
497 {
498 eBindProducts+=eBindHe3;
499 }
500 else if(tmpHadrons->operator[](i)->GetDefinition() == G4Alpha::Alpha())
501 {
502 eBindProducts+=eBindA;
503 ia++;
504 }
505 }
506
507 theGammaEnergy += eBindProducts;
508
509#ifdef G4PHPDEBUG
510 if( std::getenv("G4ParticleHPDebug")) G4cout << " G4ParticleHPInelasticBaseFS::BaseApply gamma Energy " << theGammaEnergy << " eBindProducts " << eBindProducts << G4endl;
511#endif
512
513 // Special treatment for Be9 + n -> 2n + Be8 -> 2n + a + a
514 if ( (G4int)(theBaseZ+eps) == 4 && (G4int)(theBaseA+eps) == 9 )
515 {
516 // This only valid for G4NDL3.13,,,
517 if ( std::abs( theNuclearMassDifference -
519 G4NucleiProperties::GetBindingEnergy( 9 , 4 ) ) ) < 1*CLHEP::keV
520 && ia == 2 )
521 {
522 theGammaEnergy -= (2*eBindA);
523 }
524 }
525
526 G4ReactionProductVector * theOtherPhotons = nullptr;
527 G4int iLevel;
528 while(theGammaEnergy>=theGammas.GetLevelEnergy(0)) // Loop checking, 11.05.2015, T. Koi
529 {
530 for(iLevel=theGammas.GetNumberOfLevels()-1; iLevel>=0; --iLevel)
531 {
532 if(theGammas.GetLevelEnergy(iLevel)<theGammaEnergy) break;
533 }
534 if(iLevel==0||iLevel==theGammas.GetNumberOfLevels()-1)
535 {
536 theOtherPhotons = theGammas.GetDecayGammas(iLevel);
537#ifdef G4PHPDEBUG
538 if( std::getenv("G4ParticleHPDebug"))
539 G4cout << " G4ParticleHPInelasticBaseFS::BaseApply adding gamma from level "
540 << iLevel << " "
541 << theOtherPhotons->operator[](ii)->GetKineticEnergy(
542 ) << G4endl;
543#endif
544 }
545 else
546 {
547 G4double random = G4UniformRand();
548 G4double eLow = theGammas.GetLevelEnergy(iLevel);
549 G4double eHigh = theGammas.GetLevelEnergy(iLevel+1);
550 if(random > (eHigh-eLow)/(theGammaEnergy-eLow)) iLevel++;
551 theOtherPhotons = theGammas.GetDecayGammas(iLevel);
552 }
553 if(thePhotons==0) thePhotons = new G4ReactionProductVector;
554 if(theOtherPhotons != 0)
555 {
556 for(std::size_t iii=0; iii<theOtherPhotons->size(); ++iii)
557 {
558 thePhotons->push_back(theOtherPhotons->operator[](iii));
559#ifdef G4PHPDEBUG
560 if( std::getenv("G4ParticleHPDebug"))
561 G4cout << iii << " G4ParticleHPInelasticBaseFS::BaseApply adding gamma " << theOtherPhotons->operator[](iii)->GetKineticEnergy() << G4endl;
562#endif
563 }
564 delete theOtherPhotons;
565 }
566 theGammaEnergy -= theGammas.GetLevelEnergy(iLevel);
567 if(iLevel == -1) break;
568 }
569 }
570 }
571
572 // fill the result
573 std::size_t nSecondaries = tmpHadrons->size();
574 std::size_t nPhotons = 0;
575 if(thePhotons!=0) { nPhotons = thePhotons->size(); }
576 nSecondaries += nPhotons;
577 G4DynamicParticle * theSec;
578#ifdef G4PHPDEBUG
579 if( std::getenv("G4ParticleHPDebug"))
580 G4cout << " G4ParticleHPInelasticBaseFS::BaseApply N hadrons "
581 << nSecondaries-nPhotons << G4endl;
582#endif
583
584 for(i=0; i<nSecondaries-nPhotons; ++i)
585 {
586 theSec = new G4DynamicParticle;
587 theSec->SetDefinition(tmpHadrons->operator[](i)->GetDefinition());
588 theSec->SetMomentum(tmpHadrons->operator[](i)->GetMomentum());
589 theResult.Get()->AddSecondary(theSec, secID);
590#ifdef G4PHPDEBUG
591 if( std::getenv("G4ParticleHPDebug")) G4cout << this << " G4ParticleHPInelasticBaseFS::BaseApply add secondary2 " << theSec->GetParticleDefinition()->GetParticleName() << " E= " << theSec->GetKineticEnergy() << " NSECO " << theResult.Get()->GetNumberOfSecondaries() << G4endl;
592#endif
593 delete tmpHadrons->operator[](i);
594 }
595#ifdef G4PHPDEBUG
596 if( std::getenv("G4ParticleHPDebug")) G4cout << " G4ParticleHPInelasticBaseFS::BaseApply N photons " << nPhotons << G4endl;
597#endif
598 if(thePhotons != 0)
599 {
600 for(i=0; i<nPhotons; ++i)
601 {
602 theSec = new G4DynamicParticle;
603 theSec->SetDefinition(thePhotons->operator[](i)->GetDefinition());
604 theSec->SetMomentum(thePhotons->operator[](i)->GetMomentum());
605 theResult.Get()->AddSecondary(theSec, secID);
606#ifdef G4PHPDEBUG
607 if( std::getenv("G4ParticleHPDebug")) G4cout << this << " G4ParticleHPInelasticBaseFS::BaseApply add secondary3 " << theSec->GetParticleDefinition()->GetParticleName() << " E= " << theSec->GetKineticEnergy() << " NSECO " << theResult.Get()->GetNumberOfSecondaries() << G4endl;
608#endif
609 delete thePhotons->operator[](i);
610 }
611 }
612
613 // some garbage collection
614 delete thePhotons;
615 delete tmpHadrons;
616
618 G4LorentzVector targ_4p_lab ( theTarget.GetMomentum() , std::sqrt( targ_pd->GetPDGMass()*targ_pd->GetPDGMass() + theTarget.GetMomentum().mag2() ) );
619 G4LorentzVector proj_4p_lab = theTrack.Get4Momentum();
620 G4LorentzVector init_4p_lab = proj_4p_lab + targ_4p_lab;
621
622 //if data in MF=6 format (no correlated particle emission), then adjust_final_state can give severe errors:
623 if(theEnergyAngData==0){adjust_final_state ( init_4p_lab );}
624
625 // clean up the primary neutron
627}
@ stopAndKill
std::vector< G4ReactionProduct * > G4ReactionProductVector
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
#define G4UniformRand()
Definition: Randomize.hh:52
Hep3Vector unit() const
double mag2() const
double mag() const
Hep3Vector vect() const
static G4Alpha * Alpha()
Definition: G4Alpha.cc:88
value_type & Get() const
Definition: G4Cache.hh:315
void Put(const value_type &val) const
Definition: G4Cache.hh:321
static G4Deuteron * Deuteron()
Definition: G4Deuteron.cc:93
void SetDefinition(const G4ParticleDefinition *aParticleDefinition)
const G4ParticleDefinition * GetParticleDefinition() const
G4double GetKineticEnergy() const
void SetMomentum(const G4ThreeVector &momentum)
void SetStatusChange(G4HadFinalStateStatus aS)
void AddSecondary(G4DynamicParticle *aP, G4int mod=-1)
std::size_t GetNumberOfSecondaries() const
const G4Material * GetMaterial() const
const G4ParticleDefinition * GetDefinition() const
G4double GetKineticEnergy() const
const G4LorentzVector & Get4Momentum() const
static G4He3 * He3()
Definition: G4He3.cc:93
G4ParticleDefinition * GetIon(G4int Z, G4int A, G4int lvl=0)
Definition: G4IonTable.cc:522
static G4IonTable * GetIonTable()
Definition: G4IonTable.cc:170
G4double GetTemperature() const
Definition: G4Material.hh:177
static G4Neutron * Neutron()
Definition: G4Neutron.cc:103
static G4double GetBindingEnergy(const G4int A, const G4int Z)
static G4double GetNuclearMass(const G4double A, const G4double Z)
G4ReactionProduct GetBiasedThermalNucleus(G4double aMass, G4ThreeVector aVelocity, G4double temp=-1) const
Definition: G4Nucleus.cc:118
G4int GetAtomicNumber() const
G4double GetPDGCharge() const
const G4String & GetParticleName() const
void SetTarget(const G4ReactionProduct &aTarget)
void SetProjectileRP(const G4ReactionProduct &anIncidentParticleRP)
void SampleAndUpdate(G4ReactionProduct &anIncidentParticle)
G4ReactionProductVector * GetDecayGammas(G4int aLevel)
G4double GetLevelEnergy(G4int aLevel)
void SetProjectileRP(G4ReactionProduct &aIncidentPart)
void SetTarget(G4ReactionProduct &aTarget)
G4ReactionProductVector * Sample(G4double anEnergy)
G4double Sample(G4double anEnergy, G4int &it)
G4ParticleDefinition * theProjectile
G4Cache< G4HadFinalState * > theResult
void adjust_final_state(G4LorentzVector)
static G4ParticleHPManager * GetInstance()
G4ReactionProduct * Sample(G4double anEnergy, G4double massCode, G4double mass)
void Init(G4double aMass, G4int aCount)
G4ReactionProductVector * GetPhotons(G4double anEnergy)
static G4Proton * Proton()
Definition: G4Proton.cc:92
void SetMomentum(const G4double x, const G4double y, const G4double z)
void SetTotalEnergy(const G4double en)
G4double GetKineticEnergy() const
const G4ParticleDefinition * GetDefinition() const
G4double GetTotalEnergy() const
G4ThreeVector GetMomentum() const
void Lorentz(const G4ReactionProduct &p1, const G4ReactionProduct &p2)
void SetDefinition(const G4ParticleDefinition *aParticleDefinition)
void SetKineticEnergy(const G4double en)
G4double GetMass() const
static G4Triton * Triton()
Definition: G4Triton.cc:93
void SetProjectileRP(G4ReactionProduct *aIncidentParticleRP)
void SetTarget(G4ReactionProduct *aTarget)

Referenced by G4ParticleHP2AInelasticFS::ApplyYourself(), G4ParticleHP2N2AInelasticFS::ApplyYourself(), G4ParticleHP2NAInelasticFS::ApplyYourself(), G4ParticleHP2NDInelasticFS::ApplyYourself(), G4ParticleHP2NInelasticFS::ApplyYourself(), G4ParticleHP2NPInelasticFS::ApplyYourself(), G4ParticleHP2PInelasticFS::ApplyYourself(), G4ParticleHP3AInelasticFS::ApplyYourself(), G4ParticleHP3NAInelasticFS::ApplyYourself(), G4ParticleHP3NInelasticFS::ApplyYourself(), G4ParticleHP3NPInelasticFS::ApplyYourself(), G4ParticleHP4NInelasticFS::ApplyYourself(), G4ParticleHPD2AInelasticFS::ApplyYourself(), G4ParticleHPDAInelasticFS::ApplyYourself(), G4ParticleHPN2AInelasticFS::ApplyYourself(), G4ParticleHPN2PInelasticFS::ApplyYourself(), G4ParticleHPN3AInelasticFS::ApplyYourself(), G4ParticleHPNAInelasticFS::ApplyYourself(), G4ParticleHPND2AInelasticFS::ApplyYourself(), G4ParticleHPNDInelasticFS::ApplyYourself(), G4ParticleHPNHe3InelasticFS::ApplyYourself(), G4ParticleHPNPAInelasticFS::ApplyYourself(), G4ParticleHPNPInelasticFS::ApplyYourself(), G4ParticleHPNT2AInelasticFS::ApplyYourself(), G4ParticleHPNTInelasticFS::ApplyYourself(), G4ParticleHPNXInelasticFS::ApplyYourself(), G4ParticleHPPAInelasticFS::ApplyYourself(), G4ParticleHPPDInelasticFS::ApplyYourself(), G4ParticleHPPTInelasticFS::ApplyYourself(), and G4ParticleHPT2AInelasticFS::ApplyYourself().

◆ GetXsec() [1/2]

virtual G4ParticleHPVector * G4ParticleHPInelasticBaseFS::GetXsec ( )
inlinevirtual

Reimplemented from G4ParticleHPFinalState.

Definition at line 87 of file G4ParticleHPInelasticBaseFS.hh.

87{return theXsection;}

◆ GetXsec() [2/2]

virtual G4double G4ParticleHPInelasticBaseFS::GetXsec ( G4double  anEnergy)
inlinevirtual

Reimplemented from G4ParticleHPFinalState.

Definition at line 82 of file G4ParticleHPInelasticBaseFS.hh.

83 {
84 return std::max(0., theXsection->GetY(anEnergy));
85 }
G4double GetY(G4double x)

◆ Init()

void G4ParticleHPInelasticBaseFS::Init ( G4double  A,
G4double  Z,
G4int  M,
G4String dirName,
G4String bit,
G4ParticleDefinition  
)
virtual

Implements G4ParticleHPFinalState.

Reimplemented in G4ParticleHPN2AInelasticFS, G4ParticleHPN2PInelasticFS, G4ParticleHPN3AInelasticFS, G4ParticleHPNAInelasticFS, G4ParticleHPND2AInelasticFS, G4ParticleHPNDInelasticFS, G4ParticleHPNHe3InelasticFS, G4ParticleHPNPAInelasticFS, G4ParticleHPNPInelasticFS, G4ParticleHPNT2AInelasticFS, G4ParticleHPNTInelasticFS, G4ParticleHPNXInelasticFS, G4ParticleHPPAInelasticFS, G4ParticleHPPDInelasticFS, G4ParticleHPPTInelasticFS, and G4ParticleHPT2AInelasticFS.

Definition at line 67 of file G4ParticleHPInelasticBaseFS.cc.

68{
69 gammaPath = "/Inelastic/Gammas/";
70 if(!G4FindDataDir("G4NEUTRONHPDATA"))
71 throw G4HadronicException(__FILE__, __LINE__, "Please setenv G4NEUTRONHPDATA to point to the neutron cross-section files where Inelastic/Gammas data is found.");
72 G4String tBase = G4FindDataDir("G4NEUTRONHPDATA");
73 gammaPath = tBase+gammaPath;
74 G4String tString = dirName;
75 G4bool dbool;
76 G4ParticleHPDataUsed aFile = theNames.GetName(static_cast<G4int>(A), static_cast<G4int>(Z), M,tString, bit, dbool);
77 G4String filename = aFile.GetName();
78#ifdef G4PHPDEBUG
79 if( std::getenv("G4ParticleHPDebug") ) G4cout << " G4ParticleHPInelasticBaseFS::Init FILE " << filename << G4endl;
80#endif
81 SetAZMs( A, Z, M, aFile);
82
83 if ( !dbool || ( Z<2.5 && ( std::abs(theNDLDataZ - Z)>0.0001 || std::abs(theNDLDataA - A)>0.0001)) )
84 {
85#ifdef G4PHPDEBUG
86 if(std::getenv("G4ParticleHPDebug_NamesLogging")) G4cout << "Skipped = "<< filename <<" "<<A<<" "<<Z<<G4endl;
87#endif
88 hasAnyData = false;
89 hasFSData = false;
90 hasXsec = false;
91 return;
92 }
93
94 std::istringstream theData(std::ios::in);
96
97 if(!theData) //"!" is a operator of ios
98 {
99 hasAnyData = false;
100 hasFSData = false;
101 hasXsec = false;
102 // theData.close();
103 return; // no data for exactly this isotope and FS
104 }
105 // here we go
106 G4int infoType, dataType, dummy=INT_MAX;
107 hasFSData = false;
108 while (theData >> infoType) // Loop checking, 11.05.2015, T. Koi
109 {
110 theData >> dataType;
111
112 if(dummy==INT_MAX) theData >> Qvalue >> dummy;
113 Qvalue*=CLHEP::eV;
114 // In G4NDL4.5 this value is the MT number (<1000),
115 // in others is que Q-value in eV
116
117 if(dataType==3)
118 {
119 G4int total;
120 theData >> total;
121 theXsection->Init(theData, total, CLHEP::eV);
122 }
123 else if(dataType==4)
124 {
127 hasFSData = true;
128 }
129 else if(dataType==5)
130 {
132 theEnergyDistribution->Init(theData);
133 hasFSData = true;
134 }
135 else if(dataType==6)
136 {
138 theEnergyAngData->Init(theData);
139 hasFSData = true;
140 }
141 else if(dataType==12)
142 {
145 hasFSData = true;
146 }
147 else if(dataType==13)
148 {
151 hasFSData = true;
152 }
153 else if(dataType==14)
154 {
156 hasFSData = true;
157 }
158 else if(dataType==15)
159 {
161 hasFSData = true;
162 }
163 else
164 {
165 throw G4HadronicException(__FILE__, __LINE__, "Data-type unknown to G4ParticleHPInelasticBaseFS");
166 }
167 }
168}
const char * G4FindDataDir(const char *)
#define M(row, col)
const G4int Z[17]
const G4double A[17]
void Init(std::istream &aDataFile)
void Init(std::istream &aDataFile)
void SetAZMs(G4double anA, G4double aZ, G4int aM, G4ParticleHPDataUsed used)
void GetDataStream(G4String, std::istringstream &iss)
G4ParticleHPDataUsed GetName(G4int A, G4int Z, G4String base, G4String rest, G4bool &active)
void InitEnergies(std::istream &aDataFile)
void InitAngular(std::istream &aDataFile)
void InitPartials(std::istream &aDataFile, G4ParticleHPVector *theXsec=0)
G4bool InitMean(std::istream &aDataFile)
void Init(std::istream &aDataFile, G4int total, G4double ux=1., G4double uy=1.)
G4double total(Particle const *const p1, Particle const *const p2)
#define INT_MAX
Definition: templates.hh:90

Referenced by G4ParticleHP2AInelasticFS::Init(), G4ParticleHP2N2AInelasticFS::Init(), G4ParticleHP2NAInelasticFS::Init(), G4ParticleHP2NDInelasticFS::Init(), G4ParticleHP2NInelasticFS::Init(), G4ParticleHP2NPInelasticFS::Init(), G4ParticleHP2PInelasticFS::Init(), G4ParticleHP3AInelasticFS::Init(), G4ParticleHP3NAInelasticFS::Init(), G4ParticleHP3NInelasticFS::Init(), G4ParticleHP3NPInelasticFS::Init(), G4ParticleHP4NInelasticFS::Init(), G4ParticleHPD2AInelasticFS::Init(), G4ParticleHPDAInelasticFS::Init(), G4ParticleHPN2AInelasticFS::Init(), G4ParticleHPN2PInelasticFS::Init(), G4ParticleHPN3AInelasticFS::Init(), G4ParticleHPNAInelasticFS::Init(), G4ParticleHPND2AInelasticFS::Init(), G4ParticleHPNDInelasticFS::Init(), G4ParticleHPNHe3InelasticFS::Init(), G4ParticleHPNPAInelasticFS::Init(), G4ParticleHPNPInelasticFS::Init(), G4ParticleHPNT2AInelasticFS::Init(), G4ParticleHPNTInelasticFS::Init(), G4ParticleHPNXInelasticFS::Init(), G4ParticleHPPAInelasticFS::Init(), G4ParticleHPPDInelasticFS::Init(), G4ParticleHPPTInelasticFS::Init(), and G4ParticleHPT2AInelasticFS::Init().

◆ InitGammas()

void G4ParticleHPInelasticBaseFS::InitGammas ( G4double  AR,
G4double  ZR 
)

Definition at line 50 of file G4ParticleHPInelasticBaseFS.cc.

51{
52 std::ostringstream ost;
53 ost <<gammaPath<<"z"<<ZR<<".a"<<AR;
54 G4String aName = ost.str();
55 std::ifstream from(aName, std::ios::in);
56
57 if(!from) return; // no data found for this isotope
58 std::ifstream theGammaData(aName, std::ios::in);
59
60 G4double eps = 0.001;
62 G4NucleiProperties::GetBindingEnergy(static_cast<G4int>(AR+eps),static_cast<G4int>(ZR+eps)) -
63 G4NucleiProperties::GetBindingEnergy(static_cast<G4int>(theBaseA+eps), static_cast<G4int>(theBaseZ+eps));
64 theGammas.Init(theGammaData);
65}
void Init(std::istream &aDataFile)

Referenced by G4ParticleHP2AInelasticFS::Init(), G4ParticleHP2N2AInelasticFS::Init(), G4ParticleHP2NAInelasticFS::Init(), G4ParticleHP2NDInelasticFS::Init(), G4ParticleHP2NInelasticFS::Init(), G4ParticleHP2NPInelasticFS::Init(), G4ParticleHP2PInelasticFS::Init(), G4ParticleHP3AInelasticFS::Init(), G4ParticleHP3NAInelasticFS::Init(), G4ParticleHP3NInelasticFS::Init(), G4ParticleHP3NPInelasticFS::Init(), G4ParticleHP4NInelasticFS::Init(), G4ParticleHPD2AInelasticFS::Init(), G4ParticleHPDAInelasticFS::Init(), G4ParticleHPN2AInelasticFS::Init(), G4ParticleHPN2PInelasticFS::Init(), G4ParticleHPN3AInelasticFS::Init(), G4ParticleHPNAInelasticFS::Init(), G4ParticleHPND2AInelasticFS::Init(), G4ParticleHPNDInelasticFS::Init(), G4ParticleHPNHe3InelasticFS::Init(), G4ParticleHPNPAInelasticFS::Init(), G4ParticleHPNPInelasticFS::Init(), G4ParticleHPNT2AInelasticFS::Init(), G4ParticleHPNTInelasticFS::Init(), G4ParticleHPNXInelasticFS::Init(), G4ParticleHPPAInelasticFS::Init(), G4ParticleHPPDInelasticFS::Init(), G4ParticleHPPTInelasticFS::Init(), and G4ParticleHPT2AInelasticFS::Init().

◆ New()

Member Data Documentation

◆ gammaPath

G4String G4ParticleHPInelasticBaseFS::gammaPath
protected

Definition at line 99 of file G4ParticleHPInelasticBaseFS.hh.

Referenced by Init(), and InitGammas().

◆ Qvalue

G4double G4ParticleHPInelasticBaseFS::Qvalue
protected

Definition at line 101 of file G4ParticleHPInelasticBaseFS.hh.

Referenced by BaseApply(), G4ParticleHPInelasticBaseFS(), and Init().

◆ theAngularDistribution

G4ParticleHPAngular* G4ParticleHPInelasticBaseFS::theAngularDistribution
protected

◆ theEnergyAngData

G4ParticleHPEnAngCorrelation* G4ParticleHPInelasticBaseFS::theEnergyAngData
protected

◆ theEnergyDistribution

G4ParticleHPEnergyDistribution* G4ParticleHPInelasticBaseFS::theEnergyDistribution
protected

◆ theFinalStatePhotons

G4ParticleHPPhotonDist* G4ParticleHPInelasticBaseFS::theFinalStatePhotons
protected

◆ theGammas

G4ParticleHPDeExGammas G4ParticleHPInelasticBaseFS::theGammas
protected

Definition at line 98 of file G4ParticleHPInelasticBaseFS.hh.

Referenced by BaseApply(), and InitGammas().

◆ theNuclearMassDifference

G4double G4ParticleHPInelasticBaseFS::theNuclearMassDifference
protected

◆ theXsection

G4ParticleHPVector* G4ParticleHPInelasticBaseFS::theXsection
protected

The documentation for this class was generated from the following files: