Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4CascadeRecoilMaker.cc
Go to the documentation of this file.
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25//
26//
27// Collects generated cascade data (using Collider::collide() interface)
28// and computes the nuclear recoil kinematics needed to balance the event.
29//
30// 20100909 M. Kelsey -- Inspired by G4CascadeCheckBalance
31// 20100909 M. Kelsey -- Move G4IntraNucleiCascader::goodCase() here, add
32// tolerance for "almost zero" excitation energy
33// 20100910 M. Kelsey -- Drop getRecoilFragment() in favor of user calling
34// makeRecoilFragment() with returned non-const pointer. Drop
35// handling of excitons.
36// 20100921 M. Kelsey -- Return G4InuclNuclei using "makeRecoilNuclei()".
37// Repurpose "makeRecoilFragment()" to return G4Fragment.
38// 20100924 M. Kelsey -- Remove unusable G4Fragment::SetExcitationEnergy().
39// Add deltaM to compute mass difference, use excitationEnergy
40// to force G4Fragment four-vector to match.
41// 20110214 M. Kelsey -- Follow G4InuclParticle::Model enumerator migration
42// 20110303 M. Kelsey -- Add diagnostic messages to goodNucleus().
43// 20110308 M. Kelsey -- Follow new G4Fragment interface for hole types
44// 20110722 M. Kelsey -- For IntraNucleiCascader, take G4CollOut as argument
45
46#include <vector>
47
49#include "globals.hh"
50#include "G4SystemOfUnits.hh"
51#include "G4CascadParticle.hh"
53#include "G4CollisionOutput.hh"
54#include "G4Fragment.hh"
56#include "G4InuclNuclei.hh"
57#include "G4InuclParticle.hh"
59#include "G4LorentzVector.hh"
60
61using namespace G4InuclSpecialFunctions;
62
63
64// Constructor and destructor
65
67 : G4VCascadeCollider("G4CascadeRecoilMaker"),
68 excTolerance(tolerance), inputEkin(0.),
69 recoilA(0), recoilZ(0), excitationEnergy(0.) {
70 balance = new G4CascadeCheckBalance(tolerance, tolerance, theName);
71}
72
74 delete balance;
75}
76
77
78// Standard Collider interface (non-const output "buffer")
79
81 G4InuclParticle* target,
82 G4CollisionOutput& output) {
83 if (verboseLevel > 1)
84 G4cout << " >>> G4CascadeRecoilMaker::collide" << G4endl;
85
86 // Available energy needed for "goodNucleus()" test at end
87 inputEkin = bullet ? bullet->getKineticEnergy() : 0.;
88
90 balance->collide(bullet, target, output);
91 fillRecoil();
92}
93
94// This is for use with G4IntraNucleiCascader
95
97 G4InuclParticle* target,
98 G4CollisionOutput& output,
99 const std::vector<G4CascadParticle>& cparticles) {
100 if (verboseLevel > 1)
101 G4cout << " >>> G4CascadeRecoilMaker::collide(<EP>,<CP>)" << G4endl;
102
103 // Available energy needed for "goodNucleus()" test at end
104 inputEkin = bullet ? bullet->getKineticEnergy() : 0.;
105
107 balance->collide(bullet, target, output, cparticles);
108 fillRecoil();
109}
110
111
112// Used current event configuration to construct recoil nucleus
113// NOTE: CheckBalance uses "final-initial", we want "initial-final"
114
116 recoilZ = -(balance->deltaQ()); // Charge "non-conservation"
117 recoilA = -(balance->deltaB()); // Baryon "non-conservation"
118 recoilMomentum = -(balance->deltaLV());
119
120 theExcitons.clear(); // Discard previous exciton configuraiton
121
122 // Bertini uses MeV for excitation energy
123 if (!goodFragment()) excitationEnergy = 0.;
124 else excitationEnergy = deltaM() * GeV;
125
126 // Allow for very small negative mass difference, and round to zero
127 if (std::abs(excitationEnergy) < excTolerance) excitationEnergy = 0.;
128
129 if (verboseLevel > 2) {
130 G4cout << " recoil px " << recoilMomentum.px()
131 << " py " << recoilMomentum.py() << " pz " << recoilMomentum.pz()
132 << " E " << recoilMomentum.e() << " baryon " << recoilA
133 << " charge " << recoilZ
134 << "\n recoil mass " << recoilMomentum.m()
135 << " 'excitation' energy " << excitationEnergy << G4endl;
136 }
137}
138
139
140// Construct physical nucleus from recoil parameters, if reasonable
141
144 if (verboseLevel > 1)
145 G4cout << " >>> G4CascadeRecoilMaker::makeRecoilNuclei" << G4endl;
146
147 if (!goodRecoil()) {
148 if (verboseLevel > 2 && !wholeEvent())
149 G4cout << theName << ": event recoil is not a physical nucleus" << G4endl;
150
151 return 0; // Null pointer means no fragment
152 }
153
154 theRecoilNuclei.fill(recoilMomentum, recoilA, recoilZ,
155 excitationEnergy, model);
156 theRecoilNuclei.setExitonConfiguration(theExcitons);
157
158 return &theRecoilNuclei;
159}
160
161
162// Construct pre-compound nuclear fragment from recoil parameters
163
165 if (verboseLevel > 1)
166 G4cout << " >>> G4CascadeRecoilMaker::makeRecoilFragment" << G4endl;
167
168 if (!goodRecoil()) {
169 if (verboseLevel > 2 && !wholeEvent())
170 G4cout << theName << ": event recoil is not a physical nucleus" << G4endl;
171
172 return 0; // Null pointer means no fragment
173 }
174
175 theRecoilFragment.SetZandA_asInt(recoilZ, recoilA); // Note convention!
176
177 // User may have overridden excitation energy; force four-momentum to match
178 G4double fragMass =
179 G4InuclNuclei::getNucleiMass(recoilA,recoilZ) + excitationEnergy/GeV;
180
181 G4LorentzVector fragMom; fragMom.setVectM(recoilMomentum.vect(), fragMass);
182 theRecoilFragment.SetMomentum(fragMom*GeV); // Bertini uses GeV!
183
184 // Note: exciton configuration has to be set piece by piece
185 // (arguments are Ntotal,Nproton in both cases)
186 G4int nholes = theExcitons.protonHoles+theExcitons.neutronHoles;
187 theRecoilFragment.SetNumberOfHoles(nholes, theExcitons.protonHoles);
188
189 G4int nexcit = (theExcitons.protonQuasiParticles
190 + theExcitons.neutronQuasiParticles);
191 theRecoilFragment.SetNumberOfExcitedParticle(nexcit,
192 theExcitons.protonQuasiParticles);
193
194 return &theRecoilFragment;
195}
196
197
198// Compute raw mass difference from recoil parameters
199
201 G4double nucMass = G4InuclNuclei::getNucleiMass(recoilA,recoilZ);
202 return (recoilMomentum.m() - nucMass);
203}
204
205
206// Data quality checks
207
209 return (recoilA>0 && recoilZ>=0 && recoilA >= recoilZ);
210}
211
213 return (goodFragment() && excitationEnergy > -excTolerance);
214}
215
217 if (verboseLevel > 2) {
218 G4cout << " >>> G4CascadeRecoilMaker::wholeEvent:"
219 << " A " << recoilA << " Z " << recoilZ
220 << " P " << recoilMomentum.rho() << " E " << recoilMomentum.e()
221 << "\n wholeEvent returns "
222 << (recoilA==0 && recoilZ==0 &&
223 recoilMomentum.rho() < excTolerance/GeV &&
224 std::abs(recoilMomentum.e()) < excTolerance/GeV) << G4endl;
225 }
226
227 return (recoilA==0 && recoilZ==0 &&
228 recoilMomentum.rho() < excTolerance/GeV &&
229 std::abs(recoilMomentum.e()) < excTolerance/GeV);
230}
231
232// Determine whether desired nuclear fragment is constructable outcome
233
235 if (verboseLevel > 2) {
236 G4cout << " >>> G4CascadeRecoilMaker::goodNucleus" << G4endl;
237 }
238
239 const G4double minExcitation = 0.1*keV;
240 const G4double reasonableExcitation = 7.0; // Multiple of binding energy
241 const G4double fractionalExcitation = 0.2; // Fraction of input to excite
242
243 if (!goodRecoil()) {
244 if (verboseLevel>2) {
245 if (!goodFragment()) G4cerr << " goodNucleus: invalid A/Z" << G4endl;
246 else if (excitationEnergy < -excTolerance)
247 G4cerr << " goodNucleus: negative excitation" << G4endl;
248 }
249 return false; // Not a sensible nucleus
250 }
251
252 if (excitationEnergy <= minExcitation) return true; // Effectively zero
253
254 // Maximum possible excitation energy determined by initial energy
255 G4double dm = bindingEnergy(recoilA,recoilZ);
256 G4double exc_max0z = fractionalExcitation * inputEkin*GeV;
257 G4double exc_dm = reasonableExcitation * dm;
258 G4double exc_max = (exc_max0z > exc_dm) ? exc_max0z : exc_dm;
259
260 if (verboseLevel > 3) {
261 G4cout << " eexs " << excitationEnergy << " max " << exc_max
262 << " dm " << dm << G4endl;
263 }
264
265 if (verboseLevel > 2 && excitationEnergy >= exc_max)
266 G4cerr << " goodNucleus: too much excitation" << G4endl;
267
268 return (excitationEnergy < exc_max); // Below maximum possible
269}
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
G4GLOB_DLL std::ostream G4cerr
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
void setVectM(const Hep3Vector &spatial, double mass)
Hep3Vector vect() const
void collide(G4InuclParticle *bullet, G4InuclParticle *target, G4CollisionOutput &output)
G4LorentzVector deltaLV() const
void collide(G4InuclParticle *bullet, G4InuclParticle *target, G4CollisionOutput &output)
G4InuclNuclei * makeRecoilNuclei(G4InuclParticle::Model model=G4InuclParticle::DefaultModel)
G4Fragment * makeRecoilFragment()
G4CascadeRecoilMaker(G4double tolerance=0.001 *CLHEP::MeV)
void SetNumberOfHoles(G4int valueTot, G4int valueP=0)
Definition: G4Fragment.hh:367
void SetMomentum(const G4LorentzVector &value)
Definition: G4Fragment.hh:304
void SetNumberOfExcitedParticle(G4int valueTot, G4int valueP)
Definition: G4Fragment.hh:348
void SetZandA_asInt(G4int Znew, G4int Anew)
Definition: G4Fragment.hh:268
void setExitonConfiguration(const G4ExitonConfiguration &config)
G4double getNucleiMass() const
void fill(G4int a, G4int z, G4double exc=0., Model model=DefaultModel)
G4double getKineticEnergy() const
virtual void setVerboseLevel(G4int verbose=0)
G4double bindingEnergy(G4int A, G4int Z)