Geant4 11.2.2
Toolkit for the simulation of the passage of particles through matter
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G4LowEPComptonModel.cc
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1//
2// ********************************************************************
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24// ********************************************************************
25// ********************************************************************
26// *********************************************************************
27// | |
28// | G4LowEPComptonModel-- Geant4 Monash University |
29// | low energy Compton scattering model. |
30// | J. M. C. Brown, Monash University, Australia |
31// | ## Unpolarised photons only ## |
32// | |
33// | |
34// *********************************************************************
35// | |
36// | The following is a Geant4 class to simulate the process of |
37// | bound electron Compton scattering. General code structure is |
38// | based on G4LowEnergyCompton.cc and G4LivermoreComptonModel.cc. |
39// | Algorithms for photon energy, and ejected Compton electron |
40// | direction taken from: |
41// | |
42// | J. M. C. Brown, M. R. Dimmock, J. E. Gillam and D. M. Paganin, |
43// | "A low energy bound atomic electron Compton scattering model |
44// | for Geant4", NIMB, Vol. 338, 77-88, 2014. |
45// | |
46// | The author acknowledges the work of the Geant4 collaboration |
47// | in developing the following algorithms that have been employed |
48// | or adapeted for the present software: |
49// | |
50// | # sampling of photon scattering angle, |
51// | # target element selection in composite materials, |
52// | # target shell selection in element, |
53// | # and sampling of bound electron momentum from Compton profiles. |
54// | |
55// *********************************************************************
56// | |
57// | History: |
58// | -------- |
59// | |
60// | Nov. 2011 JMCB - First version |
61// | Feb. 2012 JMCB - Migration to Geant4 9.5 |
62// | Sep. 2012 JMCB - Final fixes for Geant4 9.6 |
63// | Feb. 2013 JMCB - Geant4 9.6 FPE fix for bug 1426 |
64// | Jan. 2015 JMCB - Migration to MT (Based on Livermore |
65// | implementation) |
66// | Feb. 2016 JMCB - Geant4 10.2 FPE fix for bug 1676 |
67// | |
68// *********************************************************************
69
70#include <limits>
73#include "G4SystemOfUnits.hh"
74#include "G4Electron.hh"
76#include "G4LossTableManager.hh"
78#include "G4AtomicShell.hh"
79#include "G4AutoLock.hh"
80#include "G4Gamma.hh"
81#include "G4ShellData.hh"
82#include "G4DopplerProfile.hh"
83#include "G4Log.hh"
84#include "G4Exp.hh"
85
86//****************************************************************************
87
88using namespace std;
89namespace { G4Mutex LowEPComptonModelMutex = G4MUTEX_INITIALIZER; }
90
91G4PhysicsFreeVector* G4LowEPComptonModel::data[] = {nullptr};
92G4ShellData* G4LowEPComptonModel::shellData = nullptr;
93G4DopplerProfile* G4LowEPComptonModel::profileData = nullptr;
94
95static const G4double ln10 = G4Log(10.);
96
98 const G4String& nam)
99 : G4VEmModel(nam),isInitialised(false)
100{
101 verboseLevel=1 ;
102 // Verbosity scale:
103 // 0 = nothing
104 // 1 = warning for energy non-conservation
105 // 2 = details of energy budget
106 // 3 = calculation of cross sections, file openings, sampling of atoms
107 // 4 = entering in methods
108
109 if( verboseLevel>1 ) {
110 G4cout << "Low energy photon Compton model is constructed " << G4endl;
111 }
112
113 //Mark this model as "applicable" for atomic deexcitation
115
116 fParticleChange = nullptr;
117 fAtomDeexcitation = nullptr;
118}
119
120//****************************************************************************
121
123{
124 if(IsMaster()) {
125 delete shellData;
126 shellData = nullptr;
127 delete profileData;
128 profileData = nullptr;
129 }
130}
131
132//****************************************************************************
133
135 const G4DataVector& cuts)
136{
137 if (verboseLevel > 1) {
138 G4cout << "Calling G4LowEPComptonModel::Initialise()" << G4endl;
139 }
140
141 // Initialise element selector
142 if(IsMaster()) {
143
144 // Access to elements
145 const char* path = G4FindDataDir("G4LEDATA");
146
147 G4ProductionCutsTable* theCoupleTable =
149 G4int numOfCouples = (G4int)theCoupleTable->GetTableSize();
150
151 for(G4int i=0; i<numOfCouples; ++i) {
152 const G4Material* material =
153 theCoupleTable->GetMaterialCutsCouple(i)->GetMaterial();
154 const G4ElementVector* theElementVector = material->GetElementVector();
155 std::size_t nelm = material->GetNumberOfElements();
156
157 for (std::size_t j=0; j<nelm; ++j) {
158 G4int Z = G4lrint((*theElementVector)[j]->GetZ());
159 if(Z < 1) { Z = 1; }
160 else if(Z > maxZ){ Z = maxZ; }
161
162 if( (!data[Z]) ) { ReadData(Z, path); }
163 }
164 }
165
166 // For Doppler broadening
167 if(!shellData) {
168 shellData = new G4ShellData();
169 shellData->SetOccupancyData();
170 G4String file = "/doppler/shell-doppler";
171 shellData->LoadData(file);
172 }
173 if(!profileData) { profileData = new G4DopplerProfile(); }
174
175 InitialiseElementSelectors(particle, cuts);
176 }
177
178 if (verboseLevel > 2) {
179 G4cout << "Loaded cross section files" << G4endl;
180 }
181
182 if( verboseLevel>1 ) {
183 G4cout << "G4LowEPComptonModel is initialized " << G4endl
184 << "Energy range: "
185 << LowEnergyLimit() / eV << " eV - "
186 << HighEnergyLimit() / GeV << " GeV"
187 << G4endl;
188 }
189
190 if(isInitialised) { return; }
191
192 fParticleChange = GetParticleChangeForGamma();
193 fAtomDeexcitation = G4LossTableManager::Instance()->AtomDeexcitation();
194 isInitialised = true;
195}
196
197//****************************************************************************
198
204
205//****************************************************************************
206
207void G4LowEPComptonModel::ReadData(std::size_t Z, const char* path)
208{
209 if (verboseLevel > 1)
210 {
211 G4cout << "G4LowEPComptonModel::ReadData()"
212 << G4endl;
213 }
214 if(data[Z]) { return; }
215 const char* datadir = path;
216 if(!datadir)
217 {
218 datadir = G4FindDataDir("G4LEDATA");
219 if(!datadir)
220 {
221 G4Exception("G4LowEPComptonModel::ReadData()",
222 "em0006",FatalException,
223 "Environment variable G4LEDATA not defined");
224 return;
225 }
226 }
227
228 data[Z] = new G4PhysicsFreeVector();
229
230 std::ostringstream ost;
231 ost << datadir << "/livermore/comp/ce-cs-" << Z <<".dat";
232 std::ifstream fin(ost.str().c_str());
233
234 if( !fin.is_open())
235 {
237 ed << "G4LowEPComptonModel data file <" << ost.str().c_str()
238 << "> is not opened!" << G4endl;
239 G4Exception("G4LowEPComptonModel::ReadData()",
240 "em0003",FatalException,
241 ed,"G4LEDATA version should be G4EMLOW6.34 or later");
242 return;
243 } else {
244 if(verboseLevel > 3) {
245 G4cout << "File " << ost.str()
246 << " is opened by G4LowEPComptonModel" << G4endl;
247 }
248 data[Z]->Retrieve(fin, true);
249 data[Z]->ScaleVector(MeV, MeV*barn);
250 }
251 fin.close();
252}
253
254//****************************************************************************
255
256
259 G4double GammaEnergy,
262{
263 if (verboseLevel > 3) {
264 G4cout << "G4LowEPComptonModel::ComputeCrossSectionPerAtom()"
265 << G4endl;
266 }
267 G4double cs = 0.0;
268
269 if (GammaEnergy < LowEnergyLimit()) { return 0.0; }
270
271 G4int intZ = G4lrint(Z);
272 if(intZ < 1 || intZ > maxZ) { return cs; }
273
274 G4PhysicsFreeVector* pv = data[intZ];
275
276 // if element was not initialised
277 // do initialisation safely for MT mode
278 if(!pv)
279 {
280 InitialiseForElement(0, intZ);
281 pv = data[intZ];
282 if(!pv) { return cs; }
283 }
284
285 G4int n = G4int(pv->GetVectorLength() - 1);
286 G4double e1 = pv->Energy(0);
287 G4double e2 = pv->Energy(n);
288
289 if(GammaEnergy <= e1) { cs = GammaEnergy/(e1*e1)*pv->Value(e1); }
290 else if(GammaEnergy <= e2) { cs = pv->Value(GammaEnergy)/GammaEnergy; }
291 else if(GammaEnergy > e2) { cs = pv->Value(e2)/GammaEnergy; }
292
293 return cs;
294}
295
296//****************************************************************************
297
298void G4LowEPComptonModel::SampleSecondaries(std::vector<G4DynamicParticle*>* fvect,
299 const G4MaterialCutsCouple* couple,
300 const G4DynamicParticle* aDynamicGamma,
302{
303
304 // The scattered gamma energy is sampled according to Klein - Nishina formula.
305 // then accepted or rejected depending on the Scattering Function multiplied
306 // by factor from Klein - Nishina formula.
307 // Expression of the angular distribution as Klein Nishina
308 // angular and energy distribution and Scattering fuctions is taken from
309 // D. E. Cullen "A simple model of photon transport" Nucl. Instr. Meth.
310 // Phys. Res. B 101 (1995). Method of sampling with form factors is different
311 // data are interpolated while in the article they are fitted.
312 // Reference to the article is from J. Stepanek New Photon, Positron
313 // and Electron Interaction Data for GEANT in Energy Range from 1 eV to 10
314 // TeV (draft).
315 // The random number techniques of Butcher & Messel are used
316 // (Nucl Phys 20(1960),15).
317
318 G4double photonEnergy0 = aDynamicGamma->GetKineticEnergy()/MeV;
319
320 if (verboseLevel > 3) {
321 G4cout << "G4LowEPComptonModel::SampleSecondaries() E(MeV)= "
322 << photonEnergy0/MeV << " in " << couple->GetMaterial()->GetName()
323 << G4endl;
324 }
325 // do nothing below the threshold
326 // should never get here because the XS is zero below the limit
327 if (photonEnergy0 < LowEnergyLimit())
328 return ;
329
330 G4double e0m = photonEnergy0 / electron_mass_c2 ;
331 G4ParticleMomentum photonDirection0 = aDynamicGamma->GetMomentumDirection();
332
333 // Select randomly one element in the current material
334 const G4ParticleDefinition* particle = aDynamicGamma->GetDefinition();
335 const G4Element* elm = SelectRandomAtom(couple,particle,photonEnergy0);
336 G4int Z = (G4int)elm->GetZ();
337
338 G4double LowEPCepsilon0 = 1. / (1. + 2. * e0m);
339 G4double LowEPCepsilon0Sq = LowEPCepsilon0 * LowEPCepsilon0;
340 G4double alpha1 = -std::log(LowEPCepsilon0);
341 G4double alpha2 = 0.5 * (1. - LowEPCepsilon0Sq);
342
343 G4double wlPhoton = h_Planck*c_light/photonEnergy0;
344
345 // Sample the energy of the scattered photon
346 G4double LowEPCepsilon;
347 G4double LowEPCepsilonSq;
348 G4double oneCosT;
349 G4double sinT2;
350 G4double gReject;
351
352 if (verboseLevel > 3) {
353 G4cout << "Started loop to sample gamma energy" << G4endl;
354 }
355
356 do
357 {
358 if ( alpha1/(alpha1+alpha2) > G4UniformRand())
359 {
360 LowEPCepsilon = G4Exp(-alpha1 * G4UniformRand());
361 LowEPCepsilonSq = LowEPCepsilon * LowEPCepsilon;
362 }
363 else
364 {
365 LowEPCepsilonSq = LowEPCepsilon0Sq + (1. - LowEPCepsilon0Sq) * G4UniformRand();
366 LowEPCepsilon = std::sqrt(LowEPCepsilonSq);
367 }
368
369 oneCosT = (1. - LowEPCepsilon) / ( LowEPCepsilon * e0m);
370 sinT2 = oneCosT * (2. - oneCosT);
371 G4double x = std::sqrt(oneCosT/2.) / (wlPhoton/cm);
372 G4double scatteringFunction = ComputeScatteringFunction(x, Z);
373 gReject = (1. - LowEPCepsilon * sinT2 / (1. + LowEPCepsilonSq)) * scatteringFunction;
374
375 } while(gReject < G4UniformRand()*Z);
376
377 G4double cosTheta = 1. - oneCosT;
378 G4double sinTheta = std::sqrt(sinT2);
379 G4double phi = twopi * G4UniformRand();
380 G4double dirx = sinTheta * std::cos(phi);
381 G4double diry = sinTheta * std::sin(phi);
382 G4double dirz = cosTheta ;
383
384 // Scatter photon energy and Compton electron direction - Method based on:
385 // J. M. C. Brown, M. R. Dimmock, J. E. Gillam and D. M. Paganin'
386 // "A low energy bound atomic electron Compton scattering model for Geant4"
387 // NIMB, Vol. 338, 77-88, 2014.
388
389 // Set constants and initialize scattering parameters
390 const G4double vel_c = c_light / (m/s);
391 const G4double momentum_au_to_nat = halfpi* hbar_Planck / Bohr_radius / (kg*m/s);
392 const G4double e_mass_kg = electron_mass_c2 / c_squared / kg ;
393
394 const G4int maxDopplerIterations = 1000;
395 G4double bindingE = 0.;
396 G4double pEIncident = photonEnergy0 ;
397 G4double pERecoil = -1.;
398 G4double eERecoil = -1.;
399 G4double e_alpha =0.;
400 G4double e_beta = 0.;
401
402 G4double CE_emission_flag = 0.;
403 G4double ePAU = -1;
404 G4int shellIdx = 0;
405 G4double u_temp = 0;
406 G4double cosPhiE =0;
407 G4double sinThetaE =0;
408 G4double cosThetaE =0;
409 G4int iteration = 0;
410
411 if (verboseLevel > 3) {
412 G4cout << "Started loop to sample photon energy and electron direction" << G4endl;
413 }
414
415 do{
416 // ******************************************
417 // | Determine scatter photon energy |
418 // ******************************************
419 do
420 {
421 iteration++;
422 // ********************************************
423 // | Sample bound electron information |
424 // ********************************************
425
426 // Select shell based on shell occupancy
427 shellIdx = shellData->SelectRandomShell(Z);
428 bindingE = shellData->BindingEnergy(Z,shellIdx)/MeV;
429
430 // Randomly sample bound electron momentum (memento: the data set is in Atomic Units)
431 ePAU = profileData->RandomSelectMomentum(Z,shellIdx);
432
433 // Convert to SI units
434 G4double ePSI = ePAU * momentum_au_to_nat;
435
436 //Calculate bound electron velocity and normalise to natural units
437 u_temp = sqrt( ((ePSI*ePSI)*(vel_c*vel_c)) / ((e_mass_kg*e_mass_kg)*(vel_c*vel_c)+(ePSI*ePSI)) )/vel_c;
438
439 // Sample incident electron direction, amorphous material, to scattering photon scattering plane
440 e_alpha = pi*G4UniformRand();
441 e_beta = twopi*G4UniformRand();
442
443 // Total energy of system
444
445 G4double eEIncident = electron_mass_c2 / sqrt( 1 - (u_temp*u_temp));
446 G4double systemE = eEIncident + pEIncident;
447 G4double gamma_temp = 1.0 / sqrt( 1 - (u_temp*u_temp));
448 G4double numerator = gamma_temp*electron_mass_c2*(1 - u_temp * std::cos(e_alpha));
449 G4double subdenom1 = u_temp*cosTheta*std::cos(e_alpha);
450 G4double subdenom2 = u_temp*sinTheta*std::sin(e_alpha)*std::cos(e_beta);
451 G4double denominator = (1.0 - cosTheta) + (gamma_temp*electron_mass_c2*(1 - subdenom1 - subdenom2) / pEIncident);
452 pERecoil = (numerator/denominator);
453 eERecoil = systemE - pERecoil;
454 CE_emission_flag = pEIncident - pERecoil;
455 } while ( (iteration <= maxDopplerIterations) && (CE_emission_flag < bindingE));
456
457 // End of recalculation of photon energy with Doppler broadening
458
459 // *******************************************************
460 // | Determine ejected Compton electron direction |
461 // *******************************************************
462
463 // Calculate velocity of ejected Compton electron
464
465 G4double a_temp = eERecoil / electron_mass_c2;
466 G4double u_p_temp = sqrt(1 - (1 / (a_temp*a_temp)));
467
468 // Coefficients and terms from simulatenous equations
469 G4double sinAlpha = std::sin(e_alpha);
470 G4double cosAlpha = std::cos(e_alpha);
471 G4double sinBeta = std::sin(e_beta);
472 G4double cosBeta = std::cos(e_beta);
473
474 G4double gamma = 1.0 / sqrt(1 - (u_temp*u_temp));
475 G4double gamma_p = 1.0 / sqrt(1 - (u_p_temp*u_p_temp));
476
477 G4double var_A = pERecoil*u_p_temp*sinTheta;
478 G4double var_B = u_p_temp* (pERecoil*cosTheta-pEIncident);
479 G4double var_C = (pERecoil-pEIncident) - ( (pERecoil*pEIncident) / (gamma_p*electron_mass_c2))*(1 - cosTheta);
480
481 G4double var_D1 = gamma*electron_mass_c2*pERecoil;
482 G4double var_D2 = (1 - (u_temp*cosTheta*cosAlpha) - (u_temp*sinTheta*cosBeta*sinAlpha));
483 G4double var_D3 = ((electron_mass_c2*electron_mass_c2)*(gamma*gamma_p - 1)) - (gamma_p*electron_mass_c2*pERecoil);
484 G4double var_D = var_D1*var_D2 + var_D3;
485
486 G4double var_E1 = ((gamma*gamma_p)*(electron_mass_c2*electron_mass_c2)*(u_temp*u_p_temp)*cosAlpha);
487 G4double var_E2 = gamma_p*electron_mass_c2*pERecoil*u_p_temp*cosTheta;
488 G4double var_E = var_E1 - var_E2;
489
490 G4double var_F1 = ((gamma*gamma_p)*(electron_mass_c2*electron_mass_c2)*(u_temp*u_p_temp)*cosBeta*sinAlpha);
491 G4double var_F2 = (gamma_p*electron_mass_c2*pERecoil*u_p_temp*sinTheta);
492 G4double var_F = var_F1 - var_F2;
493
494 G4double var_G = (gamma*gamma_p)*(electron_mass_c2*electron_mass_c2)*(u_temp*u_p_temp)*sinBeta*sinAlpha;
495
496 // Two equations form a quadratic form of Wx^2 + Yx + Z = 0
497 // Coefficents and solution to quadratic
498 G4double var_W1 = (var_F*var_B - var_E*var_A)*(var_F*var_B - var_E*var_A);
499 G4double var_W2 = (var_G*var_G)*(var_A*var_A) + (var_G*var_G)*(var_B*var_B);
500 G4double var_W = var_W1 + var_W2;
501
502 G4double var_Y = 2.0*(((var_A*var_D-var_F*var_C)*(var_F*var_B-var_E*var_A)) - ((var_G*var_G)*var_B*var_C));
503
504 G4double var_Z1 = (var_A*var_D - var_F*var_C)*(var_A*var_D - var_F*var_C);
505 G4double var_Z2 = (var_G*var_G)*(var_C*var_C) - (var_G*var_G)*(var_A*var_A);
506 G4double var_Z = var_Z1 + var_Z2;
507 G4double diff1 = var_Y*var_Y;
508 G4double diff2 = 4*var_W*var_Z;
509 G4double diff = diff1 - diff2;
510
511 // Check if diff is less than zero, if so ensure it is due to FPE
512 //Determine number of digits (in decimal base) that G4double can accurately represent
513 G4double g4d_order = G4double(numeric_limits<G4double>::digits10);
514 G4double g4d_limit = std::pow(10.,-g4d_order);
515 //Confirm that diff less than zero is due FPE, i.e if abs of diff / diff1 and diff/ diff2 is less
516 //than 10^(-g4d_order), then set diff to zero
517
518 if ((diff < 0.0) && (abs(diff / diff1) < g4d_limit) && (abs(diff / diff2) < g4d_limit) )
519 {
520 diff = 0.0;
521 }
522
523
524 // Plus and minus of quadratic
525 G4double X_p = (-var_Y + sqrt (diff))/(2*var_W);
526 G4double X_m = (-var_Y - sqrt (diff))/(2*var_W);
527
528 // Floating point precision protection
529 // Check if X_p and X_m are greater than or less than 1 or -1, if so clean up FPE
530 // Issue due to propagation of FPE and only impacts 8th sig fig onwards
531 if(X_p >1){X_p=1;} if(X_p<-1){X_p=-1;}
532 if(X_m >1){X_m=1;} if(X_m<-1){X_m=-1;}
533 // End of FP protection
534
535 G4double ThetaE = 0.;
536 // Randomly sample one of the two possible solutions and determin theta angle of ejected Compton electron
537 G4double sol_select = G4UniformRand();
538
539 if (sol_select < 0.5)
540 {
541 ThetaE = std::acos(X_p);
542 }
543 if (sol_select > 0.5)
544 {
545 ThetaE = std::acos(X_m);
546 }
547 cosThetaE = std::cos(ThetaE);
548 sinThetaE = std::sin(ThetaE);
549 G4double Theta = std::acos(cosTheta);
550
551 //Calculate electron Phi
552 G4double iSinThetaE = std::sqrt(1+std::tan((pi/2.0)-ThetaE)*std::tan((pi/2.0)-ThetaE));
553 G4double iSinTheta = std::sqrt(1+std::tan((pi/2.0)-Theta)*std::tan((pi/2.0)-Theta));
554 G4double ivar_A = iSinTheta/ (pERecoil*u_p_temp);
555 // Trigs
556 cosPhiE = (var_C - var_B*cosThetaE)*(ivar_A*iSinThetaE);
557
558 // End of calculation of ejection Compton electron direction
559 //Fix for floating point errors
560
561 } while ( (iteration <= maxDopplerIterations) && (abs(cosPhiE) > 1));
562
563 // Revert to original if maximum number of iterations threshold has been reached
564 if (iteration >= maxDopplerIterations)
565 {
566 pERecoil = photonEnergy0 ;
567 bindingE = 0.;
568 dirx=0.0;
569 diry=0.0;
570 dirz=1.0;
571 }
572
573 // Set "scattered" photon direction and energy
574 G4ThreeVector photonDirection1(dirx,diry,dirz);
575 photonDirection1.rotateUz(photonDirection0);
576 fParticleChange->ProposeMomentumDirection(photonDirection1) ;
577
578 if (pERecoil > 0.)
579 {
580 fParticleChange->SetProposedKineticEnergy(pERecoil) ;
581
582 // Set ejected Compton electron direction and energy
583 G4double PhiE = std::acos(cosPhiE);
584 G4double eDirX = sinThetaE * std::cos(phi+PhiE);
585 G4double eDirY = sinThetaE * std::sin(phi+PhiE);
586 G4double eDirZ = cosThetaE;
587
588 G4double eKineticEnergy = pEIncident - pERecoil - bindingE;
589
590 G4ThreeVector eDirection(eDirX,eDirY,eDirZ);
591 eDirection.rotateUz(photonDirection0);
593 eDirection,eKineticEnergy) ;
594 fvect->push_back(dp);
595
596 }
597 else
598 {
599 fParticleChange->SetProposedKineticEnergy(0.);
600 fParticleChange->ProposeTrackStatus(fStopAndKill);
601 }
602
603 // sample deexcitation
604 //
605 if (verboseLevel > 3) {
606 G4cout << "Started atomic de-excitation " << fAtomDeexcitation << G4endl;
607 }
608
609 if(fAtomDeexcitation && iteration < maxDopplerIterations) {
610 G4int index = couple->GetIndex();
611 if(fAtomDeexcitation->CheckDeexcitationActiveRegion(index)) {
612 std::size_t nbefore = fvect->size();
614 const G4AtomicShell* shell = fAtomDeexcitation->GetAtomicShell(Z, as);
615 fAtomDeexcitation->GenerateParticles(fvect, shell, Z, index);
616 std::size_t nafter = fvect->size();
617 if(nafter > nbefore) {
618 for (std::size_t i=nbefore; i<nafter; ++i) {
619 //Check if there is enough residual energy
620 if (bindingE >= ((*fvect)[i])->GetKineticEnergy())
621 {
622 //Ok, this is a valid secondary: keep it
623 bindingE -= ((*fvect)[i])->GetKineticEnergy();
624 }
625 else
626 {
627 //Invalid secondary: not enough energy to create it!
628 //Keep its energy in the local deposit
629 delete (*fvect)[i];
630 (*fvect)[i]=nullptr;
631 }
632 }
633 }
634 }
635 }
636
637 //This should never happen
638 if(bindingE < 0.0)
639 G4Exception("G4LowEPComptonModel::SampleSecondaries()",
640 "em2051",FatalException,"Negative local energy deposit");
641
642 fParticleChange->ProposeLocalEnergyDeposit(bindingE);
643}
644
645//****************************************************************************
646
648G4LowEPComptonModel::ComputeScatteringFunction(G4double x, G4int Z)
649{
650 G4double value = Z;
651 if (x <= ScatFuncFitParam[Z][2]) {
652
653 G4double lgq = G4Log(x)/ln10;
654
655 if (lgq < ScatFuncFitParam[Z][1]) {
656 value = ScatFuncFitParam[Z][3] + lgq*ScatFuncFitParam[Z][4];
657 } else {
658 value = ScatFuncFitParam[Z][5] + lgq*ScatFuncFitParam[Z][6] +
659 lgq*lgq*ScatFuncFitParam[Z][7] + lgq*lgq*lgq*ScatFuncFitParam[Z][8];
660 }
661 value = G4Exp(value*ln10);
662 }
663 return value;
664}
665
666
667//****************************************************************************
668
669void
671 G4int Z)
672{
673 G4AutoLock l(&LowEPComptonModelMutex);
674 if(!data[Z]) { ReadData(Z); }
675 l.unlock();
676}
677
678//****************************************************************************
679
680//Fitting data to compute scattering function
681
682const G4double G4LowEPComptonModel::ScatFuncFitParam[101][9] = {
683{ 0, 0., 0., 0., 0., 0., 0., 0., 0.},
684{ 1, 6.673, 1.49968E+08, -14.352, 1.999, -143.374, 50.787, -5.951, 0.2304418},
685{ 2, 6.500, 2.50035E+08, -14.215, 1.970, -53.649, 13.892, -0.948, 0.006996759},
686{ 3, 6.551, 3.99945E+08, -13.555, 1.993, -62.090, 21.462, -2.453, 0.093416},
687{ 4, 6.500, 5.00035E+08, -13.746, 1.998, -127.906, 46.491, -5.614, 0.2262103},
688{ 5, 6.500, 5.99791E+08, -13.800, 1.998, -131.153, 47.132, -5.619, 0.2233819},
689{ 6, 6.708, 6.99842E+08, -13.885, 1.999, -128.143, 45.379, -5.325, 0.2083009},
690{ 7, 6.685, 7.99834E+08, -13.885, 2.000, -131.048, 46.314, -5.421, 0.2114925},
691{ 8, 6.669, 7.99834E+08, -13.962, 2.001, -128.225, 44.818, -5.183, 0.1997155},
692{ 9, 6.711, 7.99834E+08, -13.999, 2.000, -122.112, 42.103, -4.796, 0.1819099},
693{ 10, 6.702, 7.99834E+08, -14.044, 1.999, -110.143, 37.225, -4.143, 0.1532094},
694{ 11, 6.425, 1.00000E+09, -13.423, 1.993, -41.137, 12.313, -1.152, 0.03384553},
695{ 12, 6.542, 1.00000E+09, -13.389, 1.997, -53.549, 17.420, -1.840, 0.06431849},
696{ 13, 6.570, 1.49968E+09, -13.401, 1.997, -66.243, 22.297, -2.460, 0.09045854},
697{ 14, 6.364, 1.49968E+09, -13.452, 1.999, -78.271, 26.757, -3.008, 0.1128195},
698{ 15, 6.500, 1.49968E+09, -13.488, 1.998, -85.069, 29.164, -3.291, 0.1239113},
699{ 16, 6.500, 1.49968E+09, -13.532, 1.998, -93.640, 32.274, -3.665, 0.1388633},
700{ 17, 6.500, 1.49968E+09, -13.584, 2.000, -98.534, 33.958, -3.857, 0.1461557},
701{ 18, 6.500, 1.49968E+09, -13.618, 1.999, -100.077, 34.379, -3.891, 0.1468902},
702{ 19, 6.500, 1.99986E+09, -13.185, 1.992, -53.819, 17.528, -1.851, 0.0648722},
703{ 20, 6.490, 1.99986E+09, -13.123, 1.993, -52.221, 17.169, -1.832, 0.06502094},
704{ 21, 6.498, 1.99986E+09, -13.157, 1.994, -55.365, 18.276, -1.961, 0.07002778},
705{ 22, 6.495, 1.99986E+09, -13.183, 1.994, -57.412, 18.957, -2.036, 0.07278856},
706{ 23, 6.487, 1.99986E+09, -13.216, 1.995, -58.478, 19.270, -2.065, 0.07362722},
707{ 24, 6.500, 1.99986E+09, -13.330, 1.997, -62.192, 20.358, -2.167, 0.07666583},
708{ 25, 6.488, 1.99986E+09, -13.277, 1.997, -58.007, 18.924, -2.003, 0.0704305},
709{ 26, 6.500, 5.00035E+09, -13.292, 1.997, -61.176, 20.067, -2.141, 0.0760269},
710{ 27, 6.500, 5.00035E+09, -13.321, 1.998, -61.909, 20.271, -2.159, 0.07653559},
711{ 28, 6.500, 5.00035E+09, -13.340, 1.998, -62.402, 20.391, -2.167, 0.07664243},
712{ 29, 6.500, 5.00035E+09, -13.439, 1.998, -67.305, 21.954, -2.331, 0.0823267},
713{ 30, 6.500, 5.00035E+09, -13.383, 1.999, -62.064, 20.136, -2.122, 0.07437589},
714{ 31, 6.500, 5.00035E+09, -13.349, 1.997, -61.068, 19.808, -2.086, 0.07307488},
715{ 32, 6.500, 5.00035E+09, -13.373, 1.999, -63.126, 20.553, -2.175, 0.07660222},
716{ 33, 6.500, 5.00035E+09, -13.395, 1.999, -65.674, 21.445, -2.278, 0.08054694},
717{ 34, 6.500, 5.00035E+09, -13.417, 1.999, -69.457, 22.811, -2.442, 0.08709536},
718{ 35, 6.500, 5.00035E+09, -13.442, 2.000, -72.283, 23.808, -2.558, 0.09156808},
719{ 36, 6.500, 5.00035E+09, -13.451, 1.998, -74.696, 24.641, -2.653, 0.09516597},
720{ 37, 6.500, 5.00035E+09, -13.082, 1.991, -46.235, 14.519, -1.458, 0.04837659},
721{ 38, 6.465, 5.00035E+09, -13.022, 1.993, -41.784, 13.065, -1.300, 0.04267703},
722{ 39, 6.492, 5.00035E+09, -13.043, 1.994, -44.609, 14.114, -1.429, 0.0479348},
723{ 40, 6.499, 5.00035E+09, -13.064, 1.994, -47.142, 15.019, -1.536, 0.0521347},
724{ 41, 6.384, 5.00035E+09, -13.156, 1.996, -53.114, 17.052, -1.766, 0.06079426},
725{ 42, 6.500, 5.00035E+09, -13.176, 1.996, -54.590, 17.550, -1.822, 0.06290335},
726{ 43, 6.500, 5.00035E+09, -13.133, 1.997, -51.272, 16.423, -1.694, 0.05806108},
727{ 44, 6.500, 5.00035E+09, -13.220, 1.996, -58.314, 18.839, -1.969, 0.0684608},
728{ 45, 6.500, 5.00035E+09, -13.246, 1.998, -59.674, 19.295, -2.020, 0.07037294},
729{ 46, 6.500, 5.00035E+09, -13.407, 1.999, -72.228, 23.693, -2.532, 0.09017969},
730{ 47, 6.500, 5.00035E+09, -13.277, 1.998, -60.890, 19.647, -2.053, 0.07138694},
731{ 48, 6.500, 5.00035E+09, -13.222, 1.998, -56.152, 18.002, -1.863, 0.06410123},
732{ 49, 6.500, 5.00035E+09, -13.199, 1.997, -56.208, 18.052, -1.872, 0.06456884},
733{ 50, 6.500, 5.00035E+09, -13.215, 1.998, -58.478, 18.887, -1.973, 0.06860356},
734{ 51, 6.500, 5.00035E+09, -13.230, 1.998, -60.708, 19.676, -2.066, 0.07225841},
735{ 52, 6.500, 7.99834E+09, -13.246, 1.998, -63.341, 20.632, -2.180, 0.0767412},
736{ 53, 6.500, 5.00035E+09, -13.262, 1.998, -66.339, 21.716, -2.310, 0.08191981},
737{ 54, 6.500, 7.99834E+09, -13.279, 1.998, -67.649, 22.151, -2.357, 0.08357825},
738{ 55, 6.500, 5.00035E+09, -12.951, 1.990, -45.302, 14.219, -1.423, 0.04712317},
739{ 56, 6.425, 5.00035E+09, -12.882, 1.992, -39.825, 12.363, -1.214, 0.03931009},
740{ 57, 6.466, 2.82488E+09, -12.903, 1.992, -38.952, 11.982, -1.160, 0.03681554},
741{ 58, 6.451, 5.00035E+09, -12.915, 1.993, -41.959, 13.118, -1.302, 0.04271291},
742{ 59, 6.434, 5.00035E+09, -12.914, 1.993, -40.528, 12.555, -1.230, 0.03971407},
743{ 60, 6.444, 5.00035E+09, -12.922, 1.992, -39.986, 12.329, -1.200, 0.03843737},
744{ 61, 6.414, 7.99834E+09, -12.930, 1.993, -42.756, 13.362, -1.327, 0.0436124},
745{ 62, 6.420, 7.99834E+09, -12.938, 1.992, -42.682, 13.314, -1.319, 0.04322509},
746{ 63, 6.416, 7.99834E+09, -12.946, 1.993, -42.399, 13.185, -1.301, 0.04243861},
747{ 64, 6.443, 7.99834E+09, -12.963, 1.993, -43.226, 13.475, -1.335, 0.04377341},
748{ 65, 6.449, 7.99834E+09, -12.973, 1.993, -43.232, 13.456, -1.330, 0.04347536},
749{ 66, 6.419, 7.99834E+09, -12.966, 1.993, -42.047, 12.990, -1.270, 0.04095499},
750{ 67, 6.406, 7.99834E+09, -12.976, 1.993, -42.405, 13.106, -1.283, 0.04146024},
751{ 68, 6.424, 7.99834E+09, -12.986, 1.993, -41.974, 12.926, -1.259, 0.040435},
752{ 69, 6.417, 7.99834E+09, -12.989, 1.993, -42.132, 12.967, -1.262, 0.04048908},
753{ 70, 6.405, 7.99834E+09, -13.000, 1.994, -42.582, 13.122, -1.280, 0.04119599},
754{ 71, 6.449, 7.99834E+09, -13.015, 1.994, -42.586, 13.115, -1.278, 0.04107587},
755{ 72, 6.465, 7.99834E+09, -13.030, 1.994, -43.708, 13.509, -1.324, 0.04286491},
756{ 73, 6.447, 7.99834E+09, -13.048, 1.996, -44.838, 13.902, -1.369, 0.04457132},
757{ 74, 6.452, 7.99834E+09, -13.073, 1.997, -45.545, 14.137, -1.395, 0.04553459},
758{ 75, 6.432, 7.99834E+09, -13.082, 1.997, -46.426, 14.431, -1.428, 0.04678218},
759{ 76, 6.439, 7.99834E+09, -13.100, 1.997, -47.513, 14.806, -1.471, 0.04842566},
760{ 77, 6.432, 7.99834E+09, -13.110, 1.997, -48.225, 15.042, -1.497, 0.04938364},
761{ 78, 6.500, 7.99834E+09, -13.185, 1.997, -53.256, 16.739, -1.687, 0.05645173},
762{ 79, 6.500, 7.99834E+09, -13.200, 1.997, -53.900, 16.946, -1.709, 0.05723134},
763{ 80, 6.500, 7.99834E+09, -13.156, 1.998, -49.801, 15.536, -1.547, 0.05103522},
764{ 81, 6.500, 7.99834E+09, -13.128, 1.997, -49.651, 15.512, -1.548, 0.05123203},
765{ 82, 6.500, 7.99834E+09, -13.134, 1.997, -51.021, 16.018, -1.609, 0.05364831},
766{ 83, 6.500, 7.99834E+09, -13.148, 1.998, -52.693, 16.612, -1.679, 0.05638698},
767{ 84, 6.500, 7.99834E+09, -13.161, 1.998, -54.415, 17.238, -1.754, 0.05935566},
768{ 85, 6.500, 7.99834E+09, -13.175, 1.998, -56.083, 17.834, -1.824, 0.06206068},
769{ 86, 6.500, 7.99834E+09, -13.189, 1.998, -57.860, 18.463, -1.898, 0.0649633},
770{ 87, 6.500, 7.99834E+09, -12.885, 1.990, -39.973, 12.164, -1.162, 0.0364598},
771{ 88, 6.417, 7.99834E+09, -12.816, 1.991, -34.591, 10.338, -0.956, 0.0287409},
772{ 89, 6.442, 7.99834E+09, -12.831, 1.992, -36.002, 10.867, -1.021, 0.03136835},
773{ 90, 6.463, 7.99834E+09, -12.850, 1.993, -37.660, 11.475, -1.095, 0.03435334},
774{ 91, 6.447, 7.99834E+09, -12.852, 1.993, -37.268, 11.301, -1.071, 0.0330539},
775{ 92, 6.439, 7.99834E+09, -12.858, 1.993, -37.695, 11.438, -1.085, 0.03376669},
776{ 93, 6.437, 1.00000E+10, -12.866, 1.993, -39.010, 11.927, -1.146, 0.03630848},
777{ 94, 6.432, 7.99834E+09, -12.862, 1.993, -37.192, 11.229, -1.057, 0.0325621},
778{ 95, 6.435, 7.99834E+09, -12.869, 1.993, -37.589, 11.363, -1.072, 0.03312393},
779{ 96, 6.449, 1.00000E+10, -12.886, 1.993, -39.573, 12.095, -1.162, 0.03680527},
780{ 97, 6.446, 1.00000E+10, -12.892, 1.993, -40.007, 12.242, -1.178, 0.03737377},
781{ 98, 6.421, 1.00000E+10, -12.887, 1.993, -39.509, 12.041, -1.152, 0.03629023},
782{ 99, 6.414, 1.00000E+10, -12.894, 1.993, -39.939, 12.183, -1.168, 0.03690464},
783{100, 6.412, 1.00000E+10, -12.900, 1.993, -39.973, 12.180, -1.166, 0.036773}
784 };
785
786
787
std::vector< const G4Element * > G4ElementVector
const char * G4FindDataDir(const char *)
@ FatalException
void G4Exception(const char *originOfException, const char *exceptionCode, G4ExceptionSeverity severity, const char *description)
std::ostringstream G4ExceptionDescription
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
Definition G4Exp.hh:180
G4double G4Log(G4double x)
Definition G4Log.hh:227
#define G4MUTEX_INITIALIZER
std::mutex G4Mutex
@ fStopAndKill
double G4double
Definition G4Types.hh:83
int G4int
Definition G4Types.hh:85
const G4double alpha2
#define G4endl
Definition G4ios.hh:67
G4GLOB_DLL std::ostream G4cout
#define G4UniformRand()
Definition Randomize.hh:52
Hep3Vector & rotateUz(const Hep3Vector &)
G4double RandomSelectMomentum(G4int Z, G4int shellIndex) const
const G4ThreeVector & GetMomentumDirection() const
G4ParticleDefinition * GetDefinition() const
G4double GetKineticEnergy() const
static G4Electron * Electron()
Definition G4Electron.cc:91
G4double GetZ() const
Definition G4Element.hh:119
static G4LossTableManager * Instance()
G4VAtomDeexcitation * AtomDeexcitation()
void Initialise(const G4ParticleDefinition *, const G4DataVector &) override
void InitialiseLocal(const G4ParticleDefinition *, G4VEmModel *masterModel) override
void SampleSecondaries(std::vector< G4DynamicParticle * > *, const G4MaterialCutsCouple *, const G4DynamicParticle *, G4double tmin, G4double maxEnergy) override
G4LowEPComptonModel(const G4ParticleDefinition *p=nullptr, const G4String &nam="LowEPComptonModel")
G4double ComputeCrossSectionPerAtom(const G4ParticleDefinition *, G4double kinEnergy, G4double Z, G4double A=0, G4double cut=0, G4double emax=DBL_MAX) override
void InitialiseForElement(const G4ParticleDefinition *, G4int Z) override
const G4Material * GetMaterial() const
const G4ElementVector * GetElementVector() const
std::size_t GetNumberOfElements() const
const G4String & GetName() const
void SetProposedKineticEnergy(G4double proposedKinEnergy)
void ProposeMomentumDirection(const G4ThreeVector &Pfinal)
void ScaleVector(const G4double factorE, const G4double factorV)
G4double Energy(const std::size_t index) const
G4bool Retrieve(std::ifstream &fIn, G4bool ascii=false)
G4double Value(const G4double energy, std::size_t &lastidx) const
std::size_t GetVectorLength() const
const G4MaterialCutsCouple * GetMaterialCutsCouple(G4int i) const
std::size_t GetTableSize() const
static G4ProductionCutsTable * GetProductionCutsTable()
void SetOccupancyData()
G4double BindingEnergy(G4int Z, G4int shellIndex) const
void LoadData(const G4String &fileName)
G4int SelectRandomShell(G4int Z) const
G4bool CheckDeexcitationActiveRegion(G4int coupleIndex)
virtual const G4AtomicShell * GetAtomicShell(G4int Z, G4AtomicShellEnumerator shell)=0
void GenerateParticles(std::vector< G4DynamicParticle * > *secVect, const G4AtomicShell *, G4int Z, G4int coupleIndex)
void SetElementSelectors(std::vector< G4EmElementSelector * > *)
G4ParticleChangeForGamma * GetParticleChangeForGamma()
G4double LowEnergyLimit() const
std::vector< G4EmElementSelector * > * GetElementSelectors()
G4bool IsMaster() const
G4double HighEnergyLimit() const
const G4Element * SelectRandomAtom(const G4MaterialCutsCouple *, const G4ParticleDefinition *, G4double kineticEnergy, G4double cutEnergy=0.0, G4double maxEnergy=DBL_MAX)
void SetDeexcitationFlag(G4bool val)
void InitialiseElementSelectors(const G4ParticleDefinition *, const G4DataVector &)
void ProposeTrackStatus(G4TrackStatus status)
void ProposeLocalEnergyDeposit(G4double anEnergyPart)
int G4lrint(double ad)
Definition templates.hh:134