Geant4 10.7.0
Toolkit for the simulation of the passage of particles through matter
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G4XAnnihilationChannel.cc
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1//
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25//
26#include "globals.hh"
27#include "G4ios.hh"
30#include "G4KineticTrack.hh"
32#include "G4ResonanceWidth.hh"
34#include "G4PhysicsVector.hh"
36
38{
39 // As a first approximation the model is assumed to be valid over
40 // the entire energy range
41 lowLimit = 0.;
42 highLimit = DBL_MAX;
43 widthTable = 0;
44 partWidthTable = 0;
45}
46
48 const G4ResonanceWidth& resWidths,
49 const G4ResonancePartialWidth& resPartWidths,
50 const G4String& partWidthLabel)
51 : resonance(resDefinition)
52{
53 // Get the tabulated mass-dependent widths for the resonance
54 G4String resName = resonance->GetParticleName();
55 // cout << "HPW "<<resName<<endl;
56 G4String shortName = theNames.ShortName(resName);
57 // cout << "HPW "<<shortName<<endl;
58 // cout << "HPW "<<partWidthLabel<<endl;
59
60 widthTable = resWidths.MassDependentWidth(shortName);
61 partWidthTable = resPartWidths.MassDependentWidth(partWidthLabel);
62
63 // As a first approximation the model is assumed to be valid over
64 // the entire energy range
65 lowLimit = 0.;
66 highLimit = DBL_MAX;
67}
68
69
71{
72 if (widthTable) delete widthTable;
73 widthTable = 0;
74 if (partWidthTable) delete partWidthTable;
75 partWidthTable = 0;
76 }
77
78
80{
81 return (this == (G4XAnnihilationChannel *) &right);
82}
83
84
86{
87 return (this != (G4XAnnihilationChannel *) &right);
88}
89
90
92 const G4KineticTrack& trk2) const
93{
94 G4double sigma = 0.;
95 G4double eCM = (trk1.Get4Momentum() + trk2.Get4Momentum()).mag();
96
97 const G4ParticleDefinition* def1 = trk1.GetDefinition();
98 const G4ParticleDefinition* def2 = trk2.GetDefinition();
99
100 G4int J1 = def1->GetPDGiSpin();
101 G4int J2 = def2->GetPDGiSpin();
102 G4double m_1 = def1->GetPDGMass();
103 G4double m_2 = def2->GetPDGMass();
104
105 G4int JRes = resonance->GetPDGiSpin();
106 G4double mRes = resonance->GetPDGMass();
107
108 G4double branch = Branch(trk1,trk2);
109 G4double width = VariableWidth(trk1,trk2);
110 G4double cleb = NormalizedClebsch(trk1,trk2);
111
112 G4double S = eCM * eCM;
113 if (S == 0.) throw G4HadronicException(__FILE__, __LINE__, "G4XAnnihilationChannel::CrossSection - eCM = 0");
114
115 G4double pCM = std::sqrt((S-(m_1+m_2)*(m_1+m_2))*(S-(m_1-m_2)*(m_1-m_2))/(4.*S));
116
117 sigma = ( (JRes + 1.) / ( (J1 + 1) * (J2 + 1) )
118 * pi / (pCM * pCM) * branch * width * width /
119 ( (eCM - mRes) * (eCM - mRes) + width * width / 4.0) * cleb * hbarc_squared);
120
121// G4cout << "SS " << branch<<" "<<sigma<<" "
122// << J1 <<" "
123// <<J2<<" "
124// <<m1<<" "
125// <<m2<<" "
126// <<JRes<<" "
127// <<mRes<<" "
128// <<wRes<<" "
129// <<width<<" "
130// <<cleb<<" "
131// <<G4endl;
132 return sigma;
133}
134
135
137{
138 G4String name("XAnnihilationChannelCrossSection");
139 return name;
140}
141
142
143
145{
146 G4bool answer = InLimits(e,lowLimit,highLimit);
147
148 return answer;
149}
150
151
152G4double G4XAnnihilationChannel::Branch(const G4KineticTrack& trk1,
153 const G4KineticTrack& trk2) const
154{
155 G4double w=VariableWidth(trk1,trk2);
156 if(w==0) return 0;
157 return VariablePartialWidth(trk1,trk2) / VariableWidth(trk1,trk2);
158}
159
160G4double G4XAnnihilationChannel::VariableWidth(const G4KineticTrack& trk1,
161 const G4KineticTrack& trk2) const
162{
163 // actual production width of resonance, depending on available energy.
164
165 G4double width = resonance->GetPDGWidth();
166 G4bool dummy = false;
167 G4double sqrtS = (trk1.Get4Momentum() + trk2.Get4Momentum()).mag();
168 if (widthTable != 0)
169 {
170 width = widthTable->GetValue(sqrtS,dummy);
171 }
172 return width;
173}
174
175
176G4double G4XAnnihilationChannel::VariablePartialWidth(const G4KineticTrack& trk1,
177 const G4KineticTrack& trk2) const
178{
179 // Calculate mass dependent partial width of resonance,
180 // based on UrQMD tabulations
181
182 G4double width(0);
183
184 if (partWidthTable != 0)
185 {
186 G4double sqrtS = 0;
187 G4bool dummy = false;
188 sqrtS = (trk1.Get4Momentum() + trk2.Get4Momentum()).mag();
189 width = partWidthTable->GetValue(sqrtS,dummy);
190 }
191 else
192 {
193 width = resonance->GetPDGWidth();
194 }
195 return width;
196}
197
198
199G4double G4XAnnihilationChannel::NormalizedClebsch(const G4KineticTrack& trk1,
200 const G4KineticTrack& trk2) const
201{
202 G4double cleb = 0.;
203 const G4ParticleDefinition* def1 = trk1.GetDefinition();
204 const G4ParticleDefinition* def2 = trk2.GetDefinition();
205
206 G4int iso31 = def1->GetPDGiIsospin3();
207 G4int iso32 = def2->GetPDGiIsospin3();
208 G4int iso3 = iso31 + iso32;
209 G4int iso1 = def1->GetPDGiIsospin();
210 G4int iso2 = def2->GetPDGiIsospin();
211
212 G4int isoRes = resonance->GetPDGiIsospin();
213
214 if (isoRes < iso3) return 0.;
215 if ((iso1*iso2) == 0) return 1.;
216
217 cleb = clebsch.NormalizedClebschGordan(isoRes,iso3,iso1,iso2,iso31,iso32);
218
219 // Special case: particle-antiparticle, charge-conjugated states have the same weight
220 G4String type1 = def1->GetParticleType();
221 G4String type2 = def2->GetParticleType();
222 G4int anti = def1->GetPDGEncoding() * def2->GetPDGEncoding();
223 G4int strangeness = resonance->GetQuarkContent(3) + resonance->GetAntiQuarkContent(3);
224 if ( ((type1 == "baryon" && type2 == "baryon") ||(type1 == "meson" && type2 == "meson")) &&
225 anti < 0 && strangeness == 0)
226 {
227 if (def1->GetPDGEncoding() != -(def2->GetPDGEncoding())) cleb = 0.5 * cleb;
228 }
229
230 return cleb;
231}
232
233
234
235
236
double S(double temp)
double G4double
Definition: G4Types.hh:83
bool G4bool
Definition: G4Types.hh:86
int G4int
Definition: G4Types.hh:85
static G4double NormalizedClebschGordan(G4int twoJ, G4int twom, G4int twoJ1, G4int twoJ2, G4int twom1, G4int twom2)
Definition: G4Clebsch.cc:380
const G4ParticleDefinition * GetDefinition() const
const G4LorentzVector & Get4Momentum() const
const G4String & GetParticleType() const
G4int GetQuarkContent(G4int flavor) const
G4double GetPDGWidth() const
const G4String & GetParticleName() const
G4int GetAntiQuarkContent(G4int flavor) const
G4double GetValue(G4double theEnergy, G4bool &isOutRange) const
const G4String ShortName(const G4String &name)
virtual G4PhysicsVector * MassDependentWidth(const G4String &name) const =0
virtual G4PhysicsVector * MassDependentWidth(const G4String &name) const =0
G4bool InLimits(G4double e, G4double eLow, G4double eHigh) const
virtual G4String Name() const
G4bool operator==(const G4XAnnihilationChannel &right) const
G4bool operator!=(const G4XAnnihilationChannel &right) const
virtual G4bool IsValid(G4double e) const
virtual G4double CrossSection(const G4KineticTrack &trk1, const G4KineticTrack &trk2) const
#define DBL_MAX
Definition: templates.hh:62