Geant4 11.2.2
Toolkit for the simulation of the passage of particles through matter
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G4INCLClusterDecay.cc
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25//
26// INCL++ intra-nuclear cascade model
27// Alain Boudard, CEA-Saclay, France
28// Joseph Cugnon, University of Liege, Belgium
29// Jean-Christophe David, CEA-Saclay, France
30// Pekka Kaitaniemi, CEA-Saclay, France, and Helsinki Institute of Physics, Finland
31// Sylvie Leray, CEA-Saclay, France
32// Davide Mancusi, CEA-Saclay, France
33//
34#define INCLXX_IN_GEANT4_MODE 1
35
36#include "globals.hh"
37
38/** \file G4INCLClusterDecay.cc
39 * \brief Static class for carrying out cluster decays
40 *
41 * \date 6th July 2011
42 * \author Davide Mancusi
43 */
44
45#include "G4INCLClusterDecay.hh"
48#include "G4INCLRandom.hh"
50// #include <cassert>
51#include <algorithm>
52
53namespace G4INCL {
54
55 namespace ClusterDecay {
56
57 namespace {
58
59 /// \brief Carries out two-body decays
60 void twoBodyDecay(Cluster * const c, ClusterDecayType theDecayMode, ParticleList *decayProducts) {
61 Particle *decayParticle = 0;
62 const ThreeVector mom(0.0, 0.0, 0.0);
63 const ThreeVector pos = c->getPosition();
64
65 // Create the emitted particle
66 switch(theDecayMode) {
67 case ProtonDecay:
68 decayParticle = new Particle(Proton, mom, pos);
69 break;
70 case NeutronDecay:
71 decayParticle = new Particle(Neutron, mom, pos);
72 break;
73 case AlphaDecay:
74 decayParticle = new Cluster(2,4,0,false);
75 break;
76 case LambdaDecay:
77 decayParticle = new Particle(Lambda, mom, pos);
78 break;
79 default:
80 INCL_ERROR("Unrecognized cluster-decay mode in two-body decay: " << theDecayMode << '\n'
81 << c->print());
82 return;
83 }
84 decayParticle->makeParticipant();
85 decayParticle->setNumberOfDecays(1);
86 decayParticle->setPosition(c->getPosition());
87 decayParticle->setEmissionTime(c->getEmissionTime());
88 decayParticle->setRealMass();
89
90 // Save some variables of the mother cluster
91#ifdef INCLXX_IN_GEANT4_MODE
92 if ((c->getZ() == 1) && (c->getA() == 2) && (c->getS() == -1)) { // no Mass for A=2,Z=1,S=-1 in Geant4
93 c->setMass(2053.952);
94 if (c->getEnergy() < 2053.952) // Energy can be lower than the sum of p and Lambda masses (2053.952)...
95 c->setMomentum(c->getMomentum() * 0.) ;
96 else
97 c->setMomentum(c->getMomentum() / (std::sqrt(c->getMomentum().mag2())/std::sqrt(c->getMomentum().mag2() - 2053.952*2053.952))) ;
98 }
99#endif
100 G4double motherMass = c->getMass();
101 const ThreeVector velocity = -c->boostVector();
102
103 // Characteristics of the daughter particle
104 const G4int daughterZ = c->getZ() - decayParticle->getZ();
105 const G4int daughterA = c->getA() - decayParticle->getA();
106 const G4int daughterS = c->getS() - decayParticle->getS();
107 const G4double daughterMass = ParticleTable::getRealMass(daughterA,daughterZ,daughterS);
108
109 // The mother cluster becomes the daughter
110 c->setZ(daughterZ);
111 c->setA(daughterA);
112 c->setS(daughterS);
113 c->setMass(daughterMass);
114 c->setExcitationEnergy(0.);
115
116 // Decay kinematics in the mother rest frame
117 const G4double decayMass = decayParticle->getMass();
118// assert(motherMass-daughterMass-decayMass>-1.e-5); // Q-value should be >0
119 G4double pCM = 0.;
120 if(motherMass-daughterMass-decayMass>0.)
121 pCM = KinematicsUtils::momentumInCM(motherMass, daughterMass, decayMass);
122 const ThreeVector momentum = Random::normVector(pCM);
123 c->setMomentum(momentum);
124 c->adjustEnergyFromMomentum();
125 decayParticle->setMomentum(-momentum);
126 decayParticle->adjustEnergyFromMomentum();
127
128 // Boost to the lab frame
129 decayParticle->boost(velocity);
130 c->boost(velocity);
131
132 // Add the decay particle to the list of decay products
133 decayProducts->push_back(decayParticle);
134 }
135
136 /// \brief Carries out three-body decays
137 void threeBodyDecay(Cluster * const c, ClusterDecayType theDecayMode, ParticleList *decayProducts) {
138 Particle *decayParticle1 = 0;
139 Particle *decayParticle2 = 0;
140 const ThreeVector mom(0.0, 0.0, 0.0);
141 const ThreeVector pos = c->getPosition();
142
143 // Create the emitted particles
144 switch(theDecayMode) {
145 case TwoProtonDecay:
146 decayParticle1 = new Particle(Proton, mom, pos);
147 decayParticle2 = new Particle(Proton, mom, pos);
148 break;
149 case TwoNeutronDecay:
150 decayParticle1 = new Particle(Neutron, mom, pos);
151 decayParticle2 = new Particle(Neutron, mom, pos);
152 break;
153 default:
154 INCL_ERROR("Unrecognized cluster-decay mode in three-body decay: " << theDecayMode << '\n'
155 << c->print());
156 return;
157 }
158 decayParticle1->makeParticipant();
159 decayParticle2->makeParticipant();
160 decayParticle1->setNumberOfDecays(1);
161 decayParticle2->setNumberOfDecays(1);
162 decayParticle1->setRealMass();
163 decayParticle2->setRealMass();
164
165 // Save some variables of the mother cluster
166 const G4double motherMass = c->getMass();
167 const ThreeVector velocity = -c->boostVector();
168
169 // Masses and charges of the daughter particle and of the decay products
170 const G4int decayZ1 = decayParticle1->getZ();
171 const G4int decayA1 = decayParticle1->getA();
172 const G4int decayS1 = decayParticle1->getS();
173 const G4int decayZ2 = decayParticle2->getZ();
174 const G4int decayA2 = decayParticle2->getA();
175 const G4int decayS2 = decayParticle2->getS();
176 const G4int decayZ = decayZ1 + decayZ2;
177 const G4int decayA = decayA1 + decayA2;
178 const G4int decayS = decayS1 + decayS2;
179 const G4int daughterZ = c->getZ() - decayZ;
180 const G4int daughterA = c->getA() - decayA;
181 const G4int daughterS = c->getS() - decayS;
182 const G4double decayMass1 = decayParticle1->getMass();
183 const G4double decayMass2 = decayParticle2->getMass();
184 const G4double daughterMass = ParticleTable::getRealMass(daughterA,daughterZ,daughterS);
185
186 // Q-values
187 G4double qValue = motherMass - daughterMass - decayMass1 - decayMass2;
188// assert(qValue > -1e-5); // Q-value should be >0
189 if(qValue<0.)
190 qValue=0.;
191 const G4double qValueB = qValue * Random::shoot();
192
193 // The decay particles behave as if they had more mass until the second
194 // decay
195 const G4double decayMass = decayMass1 + decayMass2 + qValueB;
196
197 /* Stage A: mother --> daughter + (decay1+decay2) */
198
199 // The mother cluster becomes the daughter
200 c->setZ(daughterZ);
201 c->setA(daughterA);
202 c->setS(daughterS);
203 c->setMass(daughterMass);
204 c->setExcitationEnergy(0.);
205
206 // Decay kinematics in the mother rest frame
207 const G4double pCMA = KinematicsUtils::momentumInCM(motherMass, daughterMass, decayMass);
208 const ThreeVector momentumA = Random::normVector(pCMA);
209 c->setMomentum(momentumA);
210 c->adjustEnergyFromMomentum();
211 const ThreeVector decayBoostVector = momentumA/std::sqrt(decayMass*decayMass + momentumA.mag2());
212
213 /* Stage B: (decay1+decay2) --> decay1 + decay2 */
214
215 // Decay kinematics in the (decay1+decay2) rest frame
216 const G4double pCMB = KinematicsUtils::momentumInCM(decayMass, decayMass1, decayMass2);
217 const ThreeVector momentumB = Random::normVector(pCMB);
218 decayParticle1->setMomentum(momentumB);
219 decayParticle2->setMomentum(-momentumB);
220 decayParticle1->adjustEnergyFromMomentum();
221 decayParticle2->adjustEnergyFromMomentum();
222
223 // Boost decay1 and decay2 to the Stage-A decay frame
224 decayParticle1->boost(decayBoostVector);
225 decayParticle2->boost(decayBoostVector);
226
227 // Boost all particles to the lab frame
228 decayParticle1->boost(velocity);
229 decayParticle2->boost(velocity);
230 c->boost(velocity);
231
232 // Add the decay particles to the list of decay products
233 decayProducts->push_back(decayParticle1);
234 decayProducts->push_back(decayParticle2);
235 }
236
237#ifdef INCL_DO_NOT_COMPILE
238 /** \brief Disassembles unbound nuclei using a simple phase-space model
239 *
240 * The decay products are assumed to uniformly populate the momentum space
241 * (the "phase-space" naming is a long-standing but misleading convention).
242 * The generation of the final state is done by rejection, using the
243 * Raubold-Lynch method. Parts of our implementation were "inspired" by
244 * ROOT's TGenPhaseSpace class, which in turn is a translation of CERNLIB's
245 * historical GENBOD routine [CERN report 68-15 (1968)]. The ROOT
246 * implementation is documented at the following URL:
247 *
248 * http://root.cern.ch/root/html/TGenPhaseSpace.html#TGenPhaseSpace
249 */
250 void phaseSpaceDecayLegacy(Cluster * const c, ClusterDecayType theDecayMode, ParticleList *decayProducts) {
251 const G4int theA = c->getA();
252 const G4int theZ = c->getZ();
253// assert(c->getS() == 0);
254 const ThreeVector mom(0.0, 0.0, 0.0);
255 const ThreeVector pos = c->getPosition();
256
257 G4int theZStep;
258 ParticleType theEjectileType;
259 switch(theDecayMode) {
260 case ProtonUnbound:
261 theZStep = 1;
262 theEjectileType = Proton;
263 break;
264 case NeutronUnbound:
265 theZStep = 0;
266 theEjectileType = Neutron;
267 break;
268 default:
269 INCL_ERROR("Unrecognized cluster-decay mode in phase-space decay: " << theDecayMode << '\n'
270 << c->print());
271 return;
272 }
273
274 // Find the daughter cluster (first cluster which is not
275 // proton/neutron-unbound, in the sense of the table)
276 G4int finalDaughterZ, finalDaughterA;
278 finalDaughterZ=theZ;
279 finalDaughterA=theA;
280 while(clusterDecayMode[0][finalDaughterZ][finalDaughterA]==theDecayMode) { /* Loop checking, 10.07.2015, D.Mancusi */
281 finalDaughterA--;
282 finalDaughterZ -= theZStep;
283 }
284 } else {
285 finalDaughterA = 1;
286 if(theDecayMode==ProtonUnbound)
287 finalDaughterZ = 1;
288 else
289 finalDaughterZ = 0;
290 }
291// assert(finalDaughterZ<=theZ && finalDaughterA<theA && finalDaughterA>0 && finalDaughterZ>=0);
292 const G4double finalDaughterMass = ParticleTable::getRealMass(finalDaughterA, finalDaughterZ);
293
294 // Compute the available decay energy
295 const G4int nSplits = theA-finalDaughterA;
296 const G4double ejectileMass = ParticleTable::getRealMass(1, theZStep);
297 // c->getMass() can possibly contain some excitation energy, too
298 G4double availableEnergy = c->getMass() - finalDaughterMass - nSplits*ejectileMass;
299// assert(availableEnergy>-1.e-5);
300 if(availableEnergy<0.)
301 availableEnergy=0.;
302
303 // Compute an estimate of the maximum event weight
304 G4double maximumWeight = 1.;
305 G4double eMax = finalDaughterMass + availableEnergy;
306 G4double eMin = finalDaughterMass - ejectileMass;
307 for(G4int iSplit=0; iSplit<nSplits; ++iSplit) {
308 eMax += ejectileMass;
309 eMin += ejectileMass;
310 maximumWeight *= KinematicsUtils::momentumInCM(eMax, eMin, ejectileMass);
311 }
312
313 // Sample decays until the weight cutoff is satisfied
314 G4double weight;
315 std::vector<G4double> theCMMomenta;
316 std::vector<G4double> invariantMasses;
317 G4int nTries=0;
318 /* Maximum number of trials dependent on nSplits. 50 trials seems to be
319 * sufficient for small nSplits. For nSplits>=5, maximumWeight is a gross
320 * overestimate of the actual maximum weight, leading to unreasonably high
321 * rejection rates. For these cases, we set nSplits=1000, although the sane
322 * thing to do would be to improve the importance sampling (maybe by
323 * parametrising maximumWeight?).
324 */
325 G4int maxTries;
326 if(nSplits<5)
327 maxTries=50;
328 else
329 maxTries=1000;
330 do {
331 if(nTries++>maxTries) {
332 INCL_WARN("Phase-space decay exceeded the maximum number of rejections (" << maxTries
333 << "). Z=" << theZ << ", A=" << theA << ", E*=" << c->getExcitationEnergy()
334 << ", availableEnergy=" << availableEnergy
335 << ", nSplits=" << nSplits
336 << '\n');
337 break;
338 }
339
340 // Construct a sorted vector of random numbers
341 std::vector<G4double> randomNumbers;
342 for(G4int iSplit=0; iSplit<nSplits-1; ++iSplit)
343 randomNumbers.push_back(Random::shoot0());
344 std::sort(randomNumbers.begin(), randomNumbers.end());
345
346 // Divide the available decay energy in the right number of steps
347 invariantMasses.clear();
348 invariantMasses.push_back(finalDaughterMass);
349 for(G4int iSplit=0; iSplit<nSplits-1; ++iSplit)
350 invariantMasses.push_back(finalDaughterMass + (iSplit+1)*ejectileMass + randomNumbers.at(iSplit)*availableEnergy);
351 invariantMasses.push_back(c->getMass());
352
353 weight = 1.;
354 theCMMomenta.clear();
355 for(G4int iSplit=0; iSplit<nSplits; ++iSplit) {
356 G4double motherMass = invariantMasses.at(nSplits-iSplit);
357 const G4double daughterMass = invariantMasses.at(nSplits-iSplit-1);
358// assert(motherMass-daughterMass-ejectileMass>-1.e-5);
359 G4double pCM = 0.;
360 if(motherMass-daughterMass-ejectileMass>0.)
361 pCM = KinematicsUtils::momentumInCM(motherMass, daughterMass, ejectileMass);
362 theCMMomenta.push_back(pCM);
363 weight *= pCM;
364 }
365 } while(maximumWeight*Random::shoot()>weight); /* Loop checking, 10.07.2015, D.Mancusi */
366
367 for(G4int iSplit=0; iSplit<nSplits; ++iSplit) {
368 ThreeVector const velocity = -c->boostVector();
369
370#if !defined(NDEBUG) && !defined(INCLXX_IN_GEANT4_MODE)
371 const G4double motherMass = c->getMass();
372#endif
373 c->setA(c->getA() - 1);
374 c->setZ(c->getZ() - theZStep);
375 c->setMass(invariantMasses.at(nSplits-iSplit-1));
376
377 Particle *ejectile = new Particle(theEjectileType, mom, pos);
378 ejectile->setRealMass();
379
380// assert(motherMass-c->getMass()-ejectileMass>-1.e-5);
381 ThreeVector momentum;
382 momentum = Random::normVector(theCMMomenta.at(iSplit));
383 c->setMomentum(momentum);
384 c->adjustEnergyFromMomentum();
385 ejectile->setMomentum(-momentum);
386 ejectile->adjustEnergyFromMomentum();
387
388 // Boost to the lab frame
389 c->boost(velocity);
390 ejectile->boost(velocity);
391
392 // Add the decay particle to the list of decay products
393 decayProducts->push_back(ejectile);
394 }
395// assert(std::abs(c->getRealMass()-c->getMass())<1.e-3);
396 c->setExcitationEnergy(0.);
397 }
398#endif // INCL_DO_NOT_COMPILE
399
400 /** \brief Disassembles unbound nuclei using the phase-space model
401 *
402 * This implementation uses the Kopylov algorithm, defined in namespace
403 * PhaseSpaceGenerator.
404 */
405 void phaseSpaceDecay(Cluster * const c, ClusterDecayType theDecayMode, ParticleList *decayProducts) {
406 const G4int theA = c->getA();
407 const G4int theZ = c->getZ();
408 const G4int theL = (-1)*(c->getS());
409 const ThreeVector mom(0.0, 0.0, 0.0);
410 const ThreeVector pos = c->getPosition();
411
412 G4int theZStep;
413
414 ParticleType theEjectileType;
415 switch(theDecayMode) {
416 case ProtonUnbound:
417 theZStep = 1;
418 theEjectileType = Proton;
419 break;
420 case NeutronUnbound:
421 theZStep = 0;
422 theEjectileType = Neutron;
423 break;
424 case LambdaUnbound: // Will always completly decay. Append only if theA == 0 and/or theZ == 0
425 theZStep = -99;
426 if(theZ==0) theEjectileType = Neutron;
427 else theEjectileType = Proton;
428 break;
429 default:
430 INCL_ERROR("Unrecognized cluster-decay mode in phase-space decay: " << theDecayMode << '\n'
431 << c->print());
432 return;
433 }
434
435 // Find the daughter cluster (first cluster which is not
436 // proton/neutron-unbound, in the sense of the table)
437 G4int finalDaughterZ, finalDaughterA, finalDaughterL;
438 if(theZ<ParticleTable::clusterTableZSize && theA<ParticleTable::clusterTableASize && theZStep != -99) {
439 finalDaughterZ=theZ;
440 finalDaughterA=theA;
441 finalDaughterL=theL;
442 while(finalDaughterA>0 && clusterDecayMode[finalDaughterL][finalDaughterZ][finalDaughterA]!=StableCluster) { /* Loop modified, 15.01.18, J. Hirtz */
443 finalDaughterA--;
444 finalDaughterZ -= theZStep;
445 }
446 } else {
447 finalDaughterA = 1;
448 if(theDecayMode==ProtonUnbound){
449 finalDaughterZ = 1;
450 finalDaughterL = 0;
451 }
452 else if(theDecayMode==NeutronUnbound){
453 finalDaughterZ = 0;
454 finalDaughterL = 0;
455 }
456 else {
457 finalDaughterZ = 0;
458 finalDaughterL = 1;
459 }
460 }
461// assert(finalDaughterZ<=theZ && finalDaughterA<theA && finalDaughterA>0 && finalDaughterZ>=0 && finalDaughterL>=0);
462
463 // Compute the available decay energy
464 const G4int nLambda = theL-finalDaughterL;
465 const G4int nSplits = theA-finalDaughterA-nLambda;
466 // c->getMass() can possibly contain some excitation energy, too
467 const G4double availableEnergy = c->getMass();
468
469 // Save the boost vector for the cluster
470 const ThreeVector boostVector = - c->boostVector();
471
472 // Create a list of decay products
473 ParticleList products;
474 c->setA(finalDaughterA);
475 c->setZ(finalDaughterZ);
476 c->setS((-1)*finalDaughterL);
477 c->setRealMass();
478 c->setMomentum(ThreeVector());
479 c->adjustEnergyFromMomentum();
480 products.push_back(c);
481
482 for(G4int j=0; j<nLambda; ++j) {
483 Particle *ejectile = new Particle(Lambda, mom, pos);
484 ejectile->setRealMass();
485 products.push_back(ejectile);
486 }
487 for(G4int i=0; i<nSplits; ++i) {
488 Particle *ejectile = new Particle(theEjectileType, mom, pos);
489 ejectile->setRealMass();
490 products.push_back(ejectile);
491 }
492
493 PhaseSpaceGenerator::generate(availableEnergy, products);
494 products.boost(boostVector);
495
496 // Copy decay products in the output list (but skip the residue)
497 ParticleList::iterator productsIter = products.begin();
498 std::advance(productsIter, 1);
499 decayProducts->insert(decayProducts->end(), productsIter, products.end());
500
501 c->setExcitationEnergy(0.);
502 }
503
504 /** \brief Recursively decay clusters
505 *
506 * \param c cluster that should decay
507 * \param decayProducts decay products are appended to the end of this list
508 */
509 void recursiveDecay(Cluster * const c, ParticleList *decayProducts) {
510 const G4int Z = c->getZ();
511 const G4int A = c->getA();
512 const G4int S = c->getS();
513// assert(c->getExcitationEnergy()>-1.e-5);
514 if(c->getExcitationEnergy()<0.)
515 c->setExcitationEnergy(0.);
516
518 ClusterDecayType theDecayMode = clusterDecayMode[(S*(-1))][Z][A];
519
520 switch(theDecayMode) {
521 default:
522 INCL_ERROR("Unrecognized cluster-decay mode: " << theDecayMode << '\n'
523 << c->print());
524 return;
525 break;
526 case StableCluster:
527 // For stable clusters, just return
528 return;
529 break;
530 case ProtonDecay:
531 case NeutronDecay:
532 case LambdaDecay:
533 case AlphaDecay:
534 // Two-body decays
535 twoBodyDecay(c, theDecayMode, decayProducts);
536 break;
537 case TwoProtonDecay:
538 case TwoNeutronDecay:
539 // Three-body decays
540 threeBodyDecay(c, theDecayMode, decayProducts);
541 break;
542 case ProtonUnbound:
543 case NeutronUnbound:
544 case LambdaUnbound:
545 // Phase-space decays
546 phaseSpaceDecay(c, theDecayMode, decayProducts);
547 break;
548 }
549
550 // Calls itself recursively in case the produced remnant is still unstable.
551 // Sneaky, isn't it.
552 recursiveDecay(c,decayProducts);
553
554 } else {
555 // The cluster is too large for our decay-mode table. Decompose it only
556 // if Z==0 || Z==A.
557 INCL_DEBUG("Cluster is outside the decay-mode table." << c->print() << '\n');
558 if(Z==A) {
559 INCL_DEBUG("Z==A, will decompose it in free protons." << '\n');
560 phaseSpaceDecay(c, ProtonUnbound, decayProducts);
561 } else if(Z==0) {
562 INCL_DEBUG("Z==0, will decompose it in free neutrons." << '\n');
563 phaseSpaceDecay(c, NeutronUnbound, decayProducts);
564 }
565 }
566 }
567
568 } // namespace
569
570 G4bool isStable(Cluster const * const c) {
571 const G4int Z = c->getZ();
572 const G4int A = c->getA();
573 const G4int L = ((-1)*c->getS());
574 return (clusterDecayMode[L][Z][A]==StableCluster);
575 }
576
577 /** \brief Table for cluster decays
578 *
579 * Definition of "Stable": halflife > 1 ms
580 *
581 * These table includes decay data for clusters that INCL presently does
582 * not produce. It can't hurt.
583 *
584 * Unphysical nuclides (A<Z) are marked as stable, but should never be
585 * produced by INCL. If you find them in the output, something is fishy.
586 */
588 {{/* S = 0 */
589 /* A = 0 1 2 3 4 5 6 7 8 9 10 11 12 */
599 },
600 { /* S = -1 */
601 /* A = 0 1 2 3 4 5 6 7 8 9 10 11 12 */
611 },
612 { /* S = -2 */
613 /* A = 0 1 2 3 4 5 6 7 8 9 10 11 12 */
623 },
624 { /* S = -3 */
625 /* A = 0 1 2 3 4 5 6 7 8 9 10 11 12 */
635 }};
636
638 ParticleList decayProducts;
639 recursiveDecay(c, &decayProducts);
640
641 for(ParticleIter i = decayProducts.begin(), e =decayProducts.end(); i!=e; i++) (*i)->setBiasCollisionVector(c->getBiasCollisionVector());
642
643 // Correctly update the particle type
644 if(c->getA()==1) {
645// assert(c->getZ()==1 || c->getZ()==0);
646 if(c->getZ()==1)
647 c->setType(Proton);
648 else if(c->getS()==-1)
649 c->setType(Lambda);
650 else
651 c->setType(Neutron);
652 c->setRealMass();
653 }
654
655 return decayProducts;
656 }
657
658 } // namespace ClusterDecay
659} // namespace G4INCL
660
G4double S(G4double temp)
Static class for carrying out cluster decays.
#define INCL_ERROR(x)
#define INCL_WARN(x)
#define INCL_DEBUG(x)
double G4double
Definition G4Types.hh:83
bool G4bool
Definition G4Types.hh:86
int G4int
Definition G4Types.hh:85
const G4double A[17]
G4int getS() const
Returns the strangeness number.
G4int getZ() const
Returns the charge number.
std::vector< G4int > getBiasCollisionVector() const
Get the vector list of biased vertices on the particle path.
void setType(ParticleType t)
void setRealMass()
Set the mass of the Particle to its real mass.
G4int getA() const
Returns the baryon number.
G4ThreadLocal ClusterDecayType clusterDecayMode[ParticleTable::clusterTableSSize][ParticleTable::clusterTableZSize][ParticleTable::clusterTableASize]
Table for cluster decays.
ParticleList decay(Cluster *const c)
Carries out a cluster decay.
G4bool isStable(Cluster const *const c)
True if the cluster is stable.
G4double momentumInCM(Particle const *const p1, Particle const *const p2)
gives the momentum in the CM frame of two particles.
G4double getRealMass(const G4INCL::ParticleType t)
Get particle mass (in MeV/c^2)
void generate(const G4double sqrtS, ParticleList &particles)
Generate an event in the CM system.
ThreeVector normVector(G4double norm=1.)
G4double shoot0()
G4double shoot()
ParticleList::const_iterator ParticleIter
#define G4ThreadLocal
Definition tls.hh:77