187{
188
189 if (zTarget <=4) return 0.;
190
191
192
193
195
197
201
203 {
205 }
206 else
207 {
209 {
211 }
212 else
213 {
214 G4cout <<
"*** WARNING in G4ecpssrBaseLixsModel::CalculateL1CrossSection : Proton or Alpha incident particles only. " <<
G4endl;
216 return 0;
217 }
218 }
219
222 G4double systemMass =((massIncident*massTarget)/(massIncident+massTarget))/electron_mass_c2;
223 static const G4double zlshell= 4.15;
224
225 G4double screenedzTarget = zTarget-zlshell;
226 static const G4double rydbergMeV= 13.6056923e-6;
227
229
230 G4double tetal1 = (l1BindingEnergy*nl*nl)/((screenedzTarget*screenedzTarget)*rydbergMeV);
231
232
233 if (verboseLevel>0)
G4cout <<
" tetal1=" << tetal1<<
G4endl;
234
235 G4double reducedEnergy = (energyIncident*electron_mass_c2)/(massIncident*rydbergMeV*screenedzTarget*screenedzTarget);
236
237
238
239 static const G4double bohrPow2Barn=(Bohr_radius*Bohr_radius)/barn ;
240
241 G4double sigma0 = 8.*
pi*(zIncident*zIncident)*bohrPow2Barn*std::pow(screenedzTarget,-4.);
242
243
244
246
247 if (verboseLevel>0)
G4cout <<
" velocityl1=" << velocityl1<<
G4endl;
248
249 static const G4double l1AnalyticalApproximation= 1.5;
250 G4double x1 =(nl*l1AnalyticalApproximation)/velocityl1;
251
252
253
255
256 G4double electrIonizationEnergyl1=0.;
257
258
259
260
261 if ( x1<=0.035) electrIonizationEnergyl1= 0.75*
pi*(std::log(1./(x1*x1))-1.);
262 else
263 {
264 if ( x1<=3.)
265 electrIonizationEnergyl1 =
G4Exp(-2.*x1)/(0.031+(0.213*std::pow(x1,0.5))+(0.005*x1)-(0.069*std::pow(x1,3./2.))+(0.324*x1*x1));
266 else
267 {
if ( x1<=11.) electrIonizationEnergyl1 =2.*
G4Exp(-2.*x1)/std::pow(x1,1.6);}
268 }
269
270 G4double hFunctionl1 =(electrIonizationEnergyl1*2.*nl)/(tetal1*std::pow(velocityl1,3));
271
272
273 if (verboseLevel>0)
G4cout <<
" hFunctionl1=" << hFunctionl1<<
G4endl;
274
275 G4double gFunctionl1 = (1.+(9.*velocityl1)+(31.*velocityl1*velocityl1)+(49.*std::pow(velocityl1,3.))+(162.*std::pow(velocityl1,4.))+(63.*std::pow(velocityl1,5.))+(18.*std::pow(velocityl1,6.))+(1.97*std::pow(velocityl1,7.)))/std::pow(1.+velocityl1,9.);
276
277
278 if (verboseLevel>0)
G4cout <<
" gFunctionl1=" << gFunctionl1<<
G4endl;
279
280 G4double sigmaPSS_l1 = 1.+(((2.*zIncident)/(screenedzTarget*tetal1))*(gFunctionl1-hFunctionl1));
281
282
283
284
285 if (verboseLevel>0)
G4cout <<
"sigmaPSS_l1 =" << sigmaPSS_l1<<
G4endl;
286
288
289 G4double yl1Formula=0.4*(screenedzTarget/cNaturalUnit)*(screenedzTarget/cNaturalUnit)/(nl*velocityl1/sigmaPSS_l1);
290
291
292
293
294 G4double l1relativityCorrection = std::pow((1.+(1.1*yl1Formula*yl1Formula)),0.5)+yl1Formula;
295
296
297
298
299
301
303
305
306
307
308 if ( velocityl1 <20. )
309 {
310
311 L1etaOverTheta2 =(reducedEnergy* l1relativityCorrection)/((tetal1*sigmaPSS_l1)*(tetal1*sigmaPSS_l1));
312
313
314
315
316
317 if ( ((tetal1*sigmaPSS_l1) >=0.2) && ((tetal1*sigmaPSS_l1) <=2.6670) && (L1etaOverTheta2>=0.1e-3) && (L1etaOverTheta2<=0.866e2) )
318 universalFunction_l1 = FunctionFL1((tetal1*sigmaPSS_l1),L1etaOverTheta2);
319
320 if (verboseLevel>0)
G4cout <<
"at low velocity range, universalFunction_l1 =" << universalFunction_l1 <<
G4endl;
321
322 sigmaPSSR_l1 = (sigma0/(tetal1*sigmaPSS_l1))*universalFunction_l1;
323
324
325 if (verboseLevel>0)
G4cout <<
" at low velocity range, sigma PWBA L1 CS = " << sigmaPSSR_l1<<
G4endl;
326 }
327 else
328 {
329 L1etaOverTheta2 = reducedEnergy/(tetal1*tetal1);
330
331
332
333
334
335 if ( (tetal1 >=0.2) && (tetal1 <=2.6670) && (L1etaOverTheta2>=0.1e-3) && (L1etaOverTheta2<=0.866e2) )
336 universalFunction_l1 = FunctionFL1(tetal1,L1etaOverTheta2);
337
338 if (verboseLevel>0)
G4cout <<
"at medium and high velocity range, universalFunction_l1 =" << universalFunction_l1 <<
G4endl;
339
340 sigmaPSSR_l1 = (sigma0/tetal1)*universalFunction_l1;
341
342
343 if (verboseLevel>0)
G4cout <<
" sigma PWBA L1 CS at medium and high velocity range = " << sigmaPSSR_l1<<
G4endl;
344 }
345
346 G4double pssDeltal1 = (4./(systemMass *sigmaPSS_l1*tetal1))*(sigmaPSS_l1/velocityl1)*(sigmaPSS_l1/velocityl1);
347
348
349
350 if (verboseLevel>0)
G4cout <<
" pssDeltal1=" << pssDeltal1<<
G4endl;
351
352 if (pssDeltal1>1) return 0.;
353
354 G4double energyLossl1 = std::pow(1-pssDeltal1,0.5);
355
356
357
358 if (verboseLevel>0)
G4cout <<
" energyLossl1=" << energyLossl1<<
G4endl;
359
361 (8.*
pi*zIncident/systemMass)*std::pow(tetal1*sigmaPSS_l1,-2.)*std::pow(velocityl1/sigmaPSS_l1,-3.)*(zTarget/screenedzTarget);
362
363
364
365 G4double cParameterl1 =2.* coulombDeflectionl1/(energyLossl1*(energyLossl1+1.));
366
367
369
370 if (verboseLevel>0)
G4cout <<
" coulombDeflectionFunction_l1 =" << coulombDeflectionFunction_l1 <<
G4endl;
371
372 G4double crossSection_L1 = coulombDeflectionFunction_l1 * sigmaPSSR_l1;
373
374
375
376
377 if (verboseLevel>0)
G4cout <<
" crossSection_L1 =" << crossSection_L1 <<
G4endl;
378
379 if (crossSection_L1 >= 0)
380 {
381 return crossSection_L1 * barn;
382 }
383
384 else {return 0;}
385}
G4double G4Exp(G4double initial_x)
Exponential Function double precision.
G4GLOB_DLL std::ostream G4cout
G4double BindingEnergy() const
G4AtomicShell * Shell(G4int Z, size_t shellIndex) const
static G4AtomicTransitionManager * Instance()
static G4NistManager * Instance()
G4double GetAtomicMassAmu(const G4String &symb) const
G4double GetPDGMass() const
G4double GetPDGCharge() const
static G4Proton * Proton()
G4double ExpIntFunction(G4int n, G4double x)
G4double CalculateVelocity(G4int subShell, G4int zTarget, G4double massIncident, G4double energyIncident)