Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4GEMProbability.hh
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1//
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25//
26//
27//---------------------------------------------------------------------
28//
29// Geant4 header G4GEMProbability
30//
31//
32// Hadronic Process: Nuclear De-excitations
33// by V. Lara (Sept 2001)
34//
35// 18.05.2010 V.Ivanchenko trying to speedup the most slow method
36// by usage of G4Pow, integer Z and A; moved constructor,
37// destructor and virtual functions to source
38//
39
40#ifndef G4GEMProbability_h
41#define G4GEMProbability_h 1
42
44
48#include "G4VCoulombBarrier.hh"
49#include "G4NuclearLevelData.hh"
50#include "G4Pow.hh"
51#include "G4Exp.hh"
52
54{
55public:
56
57 G4GEMProbability(G4int anA, G4int aZ, G4double aSpin);
58
59 virtual ~G4GEMProbability();
60
61 // not used for evaporation
62 virtual G4double EmissionProbability(const G4Fragment& fragment,
63 G4double maxKineticEnergy);
64
65 void Dump() const;
66
67 inline G4double GetSpin(void) const;
68
69 inline void SetCoulomBarrier(const G4VCoulombBarrier * aCoulombBarrierStrategy);
70
71 inline G4double GetCoulombBarrier(const G4Fragment& fragment) const;
72
73 inline G4double CalcAlphaParam(const G4Fragment & ) const;
74
75 inline G4double CalcBetaParam(const G4Fragment & ) const;
76
77private:
78
79 G4double CalcProbability(const G4Fragment & fragment,
80 G4double MaximalKineticEnergy,
81 G4double V);
82
83 inline G4double CCoeficient(G4int) const;
84
85 inline G4double I0(G4double t);
86 inline G4double I1(G4double t, G4double tx);
87 inline G4double I2(G4double s0, G4double sx);
88 G4double I3(G4double s0, G4double sx);
89
90 // Copy constructor
93 const G4GEMProbability & operator=(const G4GEMProbability &right);
94 G4bool operator==(const G4GEMProbability &right) const;
95 G4bool operator!=(const G4GEMProbability &right) const;
96
97 // Data Members
98 G4Pow* fG4pow;
99 G4NuclearLevelData* fNucData;
100
101 G4VLevelDensityParameter * theEvapLDPptr;
102
103 // Spin is fragment spin
104 G4double Spin;
105
106 // Coulomb Barrier
107 const G4VCoulombBarrier * theCoulombBarrierPtr;
108
109protected:
110
112
113 // Resonances Energy
114 std::vector<G4double> ExcitEnergies;
115
116 // Resonances Spin
117 std::vector<G4double> ExcitSpins;
118
119 // Resonances half lifetime
120 std::vector<G4double> ExcitLifetimes;
121
122};
123
125{
126 return Spin;
127}
128
129inline void
131{
132 theCoulombBarrierPtr = aCoulombBarrierStrategy;
133}
134
135inline G4double
137{
138 G4double res = 0.0;
139 if (theCoulombBarrierPtr) {
140 G4int Acomp = fragment.GetA_asInt();
141 G4int Zcomp = fragment.GetZ_asInt();
142 res = theCoulombBarrierPtr->GetCoulombBarrier(Acomp-theA, Zcomp-theZ,
143 fragment.GetExcitationEnergy() -
144 fNucData->GetPairingCorrection(Zcomp,Acomp));
145 }
146 return res;
147}
148
149inline G4double G4GEMProbability::CCoeficient(G4int aZ) const
150{
151 //JMQ 190709 C's values from Furihata's paper
152 //(notes added on proof in Dostrovskii's paper)
153 //data = {{20, 0.}, {30, -0.06}, {40, -0.10}, {50, -0.10}};
154 G4double C = 0.0;
155 if (aZ >= 50){
156 C=-0.10/G4double(theA);
157 } else if (aZ > 20) {
158 C=(0.123482-0.00534691*aZ-0.0000610624*aZ*aZ+5.93719*1e-7*aZ*aZ*aZ+
159 1.95687*1e-8*aZ*aZ*aZ*aZ)/G4double(theA);
160 }
161 return C;
162}
163
164
166{
167 //JMQ 190709 values according to Furihata's paper (based on notes added
168 //on proof in Dostrovskii's paper)
169 G4double res;
170 if(theZ == 0) {
171 res = 0.76+1.93/fG4pow->Z13(fragment.GetA_asInt()-theA);
172 } else {
173 res = 1.0 + CCoeficient(fragment.GetZ_asInt()-theZ);
174 }
175 return res;
176}
177
178inline G4double
180{
181 //JMQ 190709 values according to Furihata's paper (based on notes added
182 //on proof in Dostrovskii's paper)
183 G4double res;
184 if(theZ == 0) {
185 res = (1.66/fG4pow->Z23(fragment.GetA_asInt()-theA)-0.05)*CLHEP::MeV/
186 CalcAlphaParam(fragment);
187 } else {
188 res = -GetCoulombBarrier(fragment);
189 }
190 return res;
191}
192
193inline G4double G4GEMProbability::I0(G4double t)
194{
195 return G4Exp(t) - 1.0;
196}
197
198inline G4double G4GEMProbability::I1(G4double t, G4double tx)
199{
200 return (t - tx + 1.0)*G4Exp(tx) - t - 1.0;
201}
202
203
204inline G4double G4GEMProbability::I2(G4double s0, G4double sx)
205{
206 G4double S = 1.0/std::sqrt(s0);
207 G4double Sx = 1.0/std::sqrt(sx);
208
209 G4double p1 = S*S*S*( 1.0 + S*S*( 1.5 + 3.75*S*S) );
210 G4double p2 = Sx*Sx*Sx*( 1.0 + Sx*Sx*( 1.5 + 3.75*Sx*Sx) )*G4Exp(sx-s0);
211
212 return p1-p2;
213}
214
215
216#endif
double S(double temp)
double C(double temp)
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
Definition: G4Exp.hh:179
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
G4double GetExcitationEnergy() const
Definition: G4Fragment.hh:275
G4int GetZ_asInt() const
Definition: G4Fragment.hh:263
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)
G4double GetSpin(void) const
void SetCoulomBarrier(const G4VCoulombBarrier *aCoulombBarrierStrategy)
G4PairingCorrection * GetPairingCorrection()
Definition: G4Pow.hh:49
G4double Z13(G4int Z) const
Definition: G4Pow.hh:123
G4double Z23(G4int Z) const
Definition: G4Pow.hh:125
virtual G4double GetCoulombBarrier(G4int ARes, G4int ZRes, G4double U) const =0