Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4GEMProbability.cc
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25//
26//
27//---------------------------------------------------------------------
28//
29// Geant4 class G4GEMProbability
30//
31//
32// Hadronic Process: Nuclear De-excitations
33// by V. Lara (Sept 2001)
34//
35//
36// Hadronic Process: Nuclear De-excitations
37// by V. Lara (Sept 2001)
38//
39// J. M. Quesada : several fixes in total GEM width
40// J. M. Quesada 14/07/2009 bug fixed in total emission width (hbarc)
41// J. M. Quesada (September 2009) several fixes:
42// -level density parameter of residual calculated at its right excitation energy.
43// -InitialLeveldensity calculated according to the right conditions of the
44// initial excited nucleus.
45// J. M. Quesada 19/04/2010 fix in emission probability calculation.
46// V.Ivanchenko 20/04/2010 added usage of G4Pow and use more safe computation
47// V.Ivanchenko 18/05/2010 trying to speedup the most slow method
48// by usage of G4Pow, integer Z and A; moved constructor,
49// destructor and virtual functions to source
50
51#include "G4GEMProbability.hh"
53#include "G4NucleiProperties.hh"
55#include "G4SystemOfUnits.hh"
56#include "G4Log.hh"
57
58G4GEMProbability:: G4GEMProbability(G4int anA, G4int aZ, G4double aSpin)
59 : G4VEmissionProbability(aZ, anA), Spin(aSpin),
60 theCoulombBarrierPtr(nullptr)
61{
62 theEvapLDPptr = new G4EvaporationLevelDensityParameter;
63 fG4pow = G4Pow::GetInstance();
64 fPlanck= CLHEP::hbar_Planck*fG4pow->logZ(2);
66}
67
69{
70 delete theEvapLDPptr;
71}
72
74 G4double MaximalKineticEnergy)
75{
76 G4double probability = 0.0;
77
78 if (MaximalKineticEnergy > 0.0 && fragment.GetExcitationEnergy() > 0.0) {
79 G4double CoulombBarrier = GetCoulombBarrier(fragment);
80
81 probability =
82 CalcProbability(fragment,MaximalKineticEnergy,CoulombBarrier);
83
84 // Next there is a loop over excited states for this channel
85 // summing probabilities
86 size_t nn = ExcitEnergies.size();
87 if (0 < nn) {
88 G4double SavedSpin = Spin;
89 for (size_t i = 0; i <nn; ++i) {
90 Spin = ExcitSpins[i];
91 // substract excitation energies
92 G4double Tmax = MaximalKineticEnergy - ExcitEnergies[i];
93 if (Tmax > 0.0) {
94 G4double width = CalcProbability(fragment,Tmax,CoulombBarrier);
95 //JMQ April 2010 added condition to prevent reported crash
96 // update probability
97 if (width > 0. && fPlanck < width*ExcitLifetimes[i]) {
98 probability += width;
99 }
100 }
101 }
102 // Restore Spin
103 Spin = SavedSpin;
104 }
105 }
106 // Normalization = probability;
107 return probability;
108}
109
110G4double G4GEMProbability::CalcProbability(const G4Fragment & fragment,
111 G4double MaximalKineticEnergy,
112 G4double V)
113
114// Calculate integrated probability (width) for evaporation channel
115{
116 G4int A = fragment.GetA_asInt();
117 G4int Z = fragment.GetZ_asInt();
118
119 G4int ResidualA = A - theA;
120 G4int ResidualZ = Z - theZ;
121 G4double U = fragment.GetExcitationEnergy();
122
123 G4double NuclearMass = fragment.ComputeGroundStateMass(theZ, theA);
124
125 G4double Alpha = CalcAlphaParam(fragment);
126 G4double Beta = CalcBetaParam(fragment);
127
128 // ***RESIDUAL***
129 //JMQ (September 2009) the following quantities refer to the RESIDUAL:
130
131 G4double delta0 = fNucData->GetPairingCorrection(ResidualZ, ResidualA);
132
133 G4double a = theEvapLDPptr->
134 LevelDensityParameter(ResidualA,ResidualZ,MaximalKineticEnergy+V-delta0);
135 G4double Ux = (2.5 + 150.0/G4double(ResidualA))*MeV;
136 G4double Ex = Ux + delta0;
137 G4double T = 1.0/(std::sqrt(a/Ux) - 1.5/Ux);
138 //JMQ fixed bug in units
139 G4double E0 = Ex - T*(G4Log(T/MeV) - G4Log(a*MeV)/4.0
140 - 1.25*G4Log(Ux/MeV) + 2.0*std::sqrt(a*Ux));
141 // ***end RESIDUAL ***
142 // ***PARENT***
143 //JMQ (September 2009) the following quantities refer to the PARENT:
144
145 G4double deltaCN = fNucData->GetPairingCorrection(Z, A);
146 G4double aCN = theEvapLDPptr->LevelDensityParameter(A, Z, U-deltaCN);
147 G4double UxCN = (2.5 + 150.0/G4double(A))*MeV;
148 G4double ExCN = UxCN + deltaCN;
149 G4double TCN = 1.0/(std::sqrt(aCN/UxCN) - 1.5/UxCN);
150 // ***end PARENT***
151
152 G4double Width;
153 G4double InitialLevelDensity;
154 G4double t = MaximalKineticEnergy/T;
155 if ( MaximalKineticEnergy < Ex ) {
156 //JMQ 190709 bug in I1 fixed (T was missing)
157 Width = (I1(t,t)*T + (Beta+V)*I0(t))/G4Exp(E0/T);
158 //JMQ 160909 fix: InitialLevelDensity has been taken away
159 //(different conditions for initial CN..)
160 } else {
161
162 //VI minor speedup
163 G4double expE0T = G4Exp(E0/T);
164 static const G4double sqrt2 = std::sqrt(2.0);
165
166 G4double tx = Ex/T;
167 G4double s0 = 2.0*std::sqrt(a*(MaximalKineticEnergy-delta0));
168 G4double sx = 2.0*std::sqrt(a*(Ex-delta0));
169 // VI: protection against FPE exception
170 if(s0 > 350.) { s0 = 350.; }
171 Width = I1(t,tx)*T/expE0T + I3(s0,sx)*G4Exp(s0)/(sqrt2*a);
172
173 // VI this cannot happen!
174 // For charged particles (Beta+V) = 0 beacuse Beta = -V
175 //if (theZ == 0) {
176 // Width += (Beta+V)*(I0(tx)/expE0T + 2.0*sqrt2*I2(s0,sx)*G4Exp(s0));
177 //}
178 }
179
180 //JMQ 14/07/2009 BIG BUG : NuclearMass is in MeV => hbarc instead of
181 // hbar_planck must be used
182 // G4double g = (2.0*Spin+1.0)*NuclearMass/(pi2* hbar_Planck*hbar_Planck);
183 G4double gg = (2.0*Spin+1.0)*NuclearMass/(pi2* hbarc*hbarc);
184
185 //JMQ 190709 fix on Rb and geometrical cross sections according to
186 // Furihata's paper (JAERI-Data/Code 2001-105, p6)
187 G4double Rb = 0.0;
188 if (theA > 4)
189 {
190 G4double Ad = fG4pow->Z13(ResidualA);
191 G4double Aj = fG4pow->Z13(theA);
192 Rb = 1.12*(Aj + Ad) - 0.86*((Aj+Ad)/(Aj*Ad))+2.85;
193 Rb *= fermi;
194 }
195 else if (theA>1)
196 {
197 G4double Ad = fG4pow->Z13(ResidualA);
198 G4double Aj = fG4pow->Z13(theA);
199 Rb=1.5*(Aj+Ad)*fermi;
200 }
201 else
202 {
203 G4double Ad = fG4pow->Z13(ResidualA);
204 Rb = 1.5*Ad*fermi;
205 }
206 G4double GeometricalXS = pi*Rb*Rb;
207 //end of JMQ fix on Rb by 190709
208
209 //JMQ 160909 fix: initial level density must be calculated according to the
210 // conditions at the initial compound nucleus
211 // (it has been removed from previous "if" for the residual)
212
213 if ( U < ExCN )
214 {
215 //JMQ fixed bug in units
216 //VI moved the computation here
217 G4double E0CN = ExCN - TCN*(G4Log(TCN/MeV) - 0.25*G4Log(aCN*MeV)
218 - 1.25*G4Log(UxCN/MeV)
219 + 2.0*std::sqrt(aCN*UxCN));
220
221 InitialLevelDensity = (pi/12.0)*G4Exp((U-E0CN)/TCN)/TCN;
222 }
223 else
224 {
225 //VI speedup
226 G4double x = U-deltaCN;
227 G4double x1 = std::sqrt(aCN*x);
228
229 InitialLevelDensity = (pi/12.0)*G4Exp(2*x1)/(x*std::sqrt(x1));
230 }
231
232 //JMQ 190709 BUG : pi instead of sqrt(pi) must be here according
233 // to Furihata's report:
234 Width *= pi*gg*GeometricalXS*Alpha/(12.0*InitialLevelDensity);
235
236 return Width;
237}
238
239G4double G4GEMProbability::I3(G4double s0, G4double sx)
240{
241 G4double s2 = s0*s0;
242 G4double sx2 = sx*sx;
243 G4double S = 1.0/std::sqrt(s0);
244 G4double S2 = S*S;
245 G4double Sx = 1.0/std::sqrt(sx);
246 G4double Sx2 = Sx*Sx;
247
248 G4double p1 = S *(2.0 + S2 *( 4.0 + S2 *( 13.5 + S2 *( 60.0 + S2 * 325.125 ))));
249 G4double p2 = Sx*Sx2 *(
250 (s2-sx2) + Sx2 *(
251 (1.5*s2+0.5*sx2) + Sx2 *(
252 (3.75*s2+0.25*sx2) + Sx2 *(
253 (12.875*s2+0.625*sx2) + Sx2 *(
254 (59.0625*s2+0.9375*sx2) + Sx2 *(324.8*s2+3.28*sx2))))));
255
256 p2 *= G4Exp(sx-s0);
257
258 return p1-p2;
259}
260
262{
264 G4double efermi = 0.0;
265 if(theA > 1) {
267 + neutron_mass_c2 - mass;
268 }
269 G4int nlev = ExcitEnergies.size();
270 G4cout << "GEM: List of Excited States for Isotope Z= "
271 << theZ << " A= " << theA << " Nlevels= " << nlev
272 << " Efermi(MeV)= " << efermi
273 << G4endl;
274 for(G4int i=0; i< nlev; ++i) {
275 G4cout << "Z= " << theZ << " A= " << theA
276 << " Mass(GeV)= " << mass/GeV
277 << " Eexc(MeV)= " << ExcitEnergies[i]
278 << " Time(ns)= " << ExcitLifetimes[i]/ns
279 << G4endl;
280 }
281 G4cout << G4endl;
282}
double S(double temp)
double A(double temperature)
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
Definition: G4Exp.hh:179
G4double G4Log(G4double x)
Definition: G4Log.hh:226
double G4double
Definition: G4Types.hh:83
int G4int
Definition: G4Types.hh:85
#define G4endl
Definition: G4ios.hh:57
G4GLOB_DLL std::ostream G4cout
G4double GetExcitationEnergy() const
Definition: G4Fragment.hh:275
G4int GetZ_asInt() const
Definition: G4Fragment.hh:263
G4double ComputeGroundStateMass(G4int Z, G4int A) const
Definition: G4Fragment.hh:248
G4int GetA_asInt() const
Definition: G4Fragment.hh:258
G4double GetCoulombBarrier(const G4Fragment &fragment) const
std::vector< G4double > ExcitSpins
std::vector< G4double > ExcitEnergies
virtual ~G4GEMProbability()
G4double CalcAlphaParam(const G4Fragment &) const
std::vector< G4double > ExcitLifetimes
G4double CalcBetaParam(const G4Fragment &) const
virtual G4double EmissionProbability(const G4Fragment &fragment, G4double maxKineticEnergy)
G4PairingCorrection * GetPairingCorrection()
static G4NuclearLevelData * GetInstance()
static G4double GetNuclearMass(const G4double A, const G4double Z)
static G4Pow * GetInstance()
Definition: G4Pow.cc:41
G4double logZ(G4int Z) const
Definition: G4Pow.hh:137
G4double Z13(G4int Z) const
Definition: G4Pow.hh:123
virtual G4double LevelDensityParameter(G4int A, G4int Z, G4double U) const =0
const G4double pi
#define ns
Definition: xmlparse.cc:614