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Geant4/materials/src/G4UCNMicroRoughnessHelper.cc

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Diff markup

Differences between /materials/src/G4UCNMicroRoughnessHelper.cc (Version 11.3.0) and /materials/src/G4UCNMicroRoughnessHelper.cc (Version 9.1)


  1 //                                                  1 
  2 // *******************************************    
  3 // * License and Disclaimer                       
  4 // *                                              
  5 // * The  Geant4 software  is  copyright of th    
  6 // * the Geant4 Collaboration.  It is provided    
  7 // * conditions of the Geant4 Software License    
  8 // * LICENSE and available at  http://cern.ch/    
  9 // * include a list of copyright holders.         
 10 // *                                              
 11 // * Neither the authors of this software syst    
 12 // * institutes,nor the agencies providing fin    
 13 // * work  make  any representation or  warran    
 14 // * regarding  this  software system or assum    
 15 // * use.  Please see the license in the file     
 16 // * for the full disclaimer and the limitatio    
 17 // *                                              
 18 // * This  code  implementation is the result     
 19 // * technical work of the GEANT4 collaboratio    
 20 // * By using,  copying,  modifying or  distri    
 21 // * any work based  on the software)  you  ag    
 22 // * use  in  resulting  scientific  publicati    
 23 // * acceptance of all terms of the Geant4 Sof    
 24 // *******************************************    
 25                                                   
 26 // This file contains the source code of vario    
 27 // calculation of microroughness.                 
 28 //                                                
 29 // see A. Steyerl, Z. Physik 254 (1972) 169.      
 30 //                                                
 31 // A description of the functions can be found    
 32                                                   
 33 #include "G4UCNMicroRoughnessHelper.hh"           
 34                                                   
 35 #include "G4PhysicalConstants.hh"                 
 36 #include "G4SystemOfUnits.hh"                     
 37 #include "globals.hh"                             
 38                                                   
 39 G4UCNMicroRoughnessHelper* G4UCNMicroRoughness    
 40                                                   
 41 //....oooOO0OOooo........oooOO0OOooo........oo    
 42                                                   
 43 G4UCNMicroRoughnessHelper::~G4UCNMicroRoughnes    
 44                                                   
 45 //....oooOO0OOooo........oooOO0OOooo........oo    
 46                                                   
 47 G4UCNMicroRoughnessHelper* G4UCNMicroRoughness    
 48 {                                                 
 49   if (fpInstance == nullptr) {                    
 50     fpInstance = new G4UCNMicroRoughnessHelper    
 51   }                                               
 52   return fpInstance;                              
 53 }                                                 
 54                                                   
 55 //....oooOO0OOooo........oooOO0OOooo........oo    
 56                                                   
 57 G4double G4UCNMicroRoughnessHelper::S2(G4doubl    
 58 {                                                 
 59   // case 1: radicand is positive,                
 60   // case 2: radicand is negative, cf. p. 174     
 61                                                   
 62   if (costheta2 >= klk2) {                        
 63     return 4 * costheta2 / (2 * costheta2 - kl    
 64   }                                               
 65                                                   
 66   return std::norm(2 * std::sqrt(costheta2) /     
 67                    (std::sqrt(costheta2) + std    
 68 }                                                 
 69                                                   
 70 //....oooOO0OOooo........oooOO0OOooo........oo    
 71                                                   
 72 G4double G4UCNMicroRoughnessHelper::SS2(G4doub    
 73 {                                                 
 74   // cf. p. 175 of the Steyerl paper              
 75                                                   
 76   return 4 * costhetas2 /                         
 77          (2 * costhetas2 + klks2 + 2 * std::sq    
 78 }                                                 
 79                                                   
 80 //....oooOO0OOooo........oooOO0OOooo........oo    
 81                                                   
 82 G4double G4UCNMicroRoughnessHelper::Fmu(G4doub    
 83   G4double phio, G4double b2, G4double w2, G4d    
 84 {                                                 
 85   G4double mu_squared;                            
 86                                                   
 87   // Checks if the distribution is peaked arou    
 88                                                   
 89   if ((std::fabs(thetai - thetao) < AngCut) &&    
 90     mu_squared = 0.;                              
 91   }                                               
 92   else {                                          
 93     // cf. p. 177 of the Steyerl paper            
 94                                                   
 95     G4double sinthetai = std::sin(thetai);        
 96     G4double sinthetao = std::sin(thetao);        
 97     mu_squared = k2 * (sinthetai * sinthetai +    
 98                         2. * sinthetai * sinth    
 99   }                                               
100                                                   
101   // cf. p. 177 of the Steyerl paper              
102                                                   
103   return b2 * w2 / twopi * std::exp(-mu_square    
104 }                                                 
105                                                   
106 //....oooOO0OOooo........oooOO0OOooo........oo    
107                                                   
108 G4double G4UCNMicroRoughnessHelper::FmuS(G4dou    
109   G4double phiSo, G4double b2, G4double w2, G4    
110 {                                                 
111   G4double mu_squared;                            
112                                                   
113   // Checks if the distribution is peaked arou    
114   // unperturbed refraction                       
115                                                   
116   if ((std::fabs(thetarefract - thetaSo) < Ang    
117     mu_squared = 0.;                              
118   }                                               
119   else {                                          
120     G4double sinthetai = std::sin(thetai);        
121     G4double sinthetaSo = std::sin(thetaSo);      
122                                                   
123     // cf. p. 177 of the Steyerl paper            
124     mu_squared = k * k * sinthetai * sinthetai    
125                  2. * k * kS * sinthetai * sin    
126   }                                               
127                                                   
128   // cf. p. 177 of the Steyerl paper              
129                                                   
130   return b2 * w2 / twopi * std::exp(-mu_square    
131 }                                                 
132                                                   
133 //....oooOO0OOooo........oooOO0OOooo........oo    
134                                                   
135 G4double G4UCNMicroRoughnessHelper::IntIplus(G    
136   G4int AngNoTheta, G4int AngNoPhi, G4double b    
137 {                                                 
138   *max = 0.;                                      
139                                                   
140   // max_theta_o saves the theta-position of t    
141   // the previous value is saved in a_max_thet    
142                                                   
143   G4double a_max_theta_o, max_theta_o = theta_    
144                                                   
145   // max_phi_o saves the phi-position of the m    
146   // the previous value is saved in a_max_phi_    
147                                                   
148   // Definition of the stepsizes in theta_o an    
149                                                   
150   G4double theta_o;                               
151   G4double phi_o;                                 
152   G4double Intens;                                
153   G4double ang_steptheta = 90. * degree / (Ang    
154   G4double ang_stepphi = 360. * degree / (AngN    
155   G4double costheta_i = std::cos(theta_i);        
156   G4double costheta_i_squared = costheta_i * c    
157                                                   
158   // (k_l/k)^2                                    
159   G4double kl4d4 =                                
160     neutron_mass_c2 / hbarc_squared * neutron_    
161                                                   
162   // (k_l/k)^2                                    
163   G4double klk2 = fermipot / E;                   
164                                                   
165   G4double costheta_o_squared;                    
166                                                   
167   // k^2                                          
168   G4double k2 = 2 * neutron_mass_c2 * E / hbar    
169                                                   
170   G4double wkeit = 0.;                            
171                                                   
172   // Loop through theta_o                         
173                                                   
174   for (theta_o = 0. * degree; theta_o <= 90. *    
175     costheta_o_squared = std::cos(theta_o) * s    
176                                                   
177     // Loop through phi_o                         
178                                                   
179     for (phi_o = -180. * degree; phi_o <= 180.    
180       // calculates probability for a certain     
181                                                   
182       Intens = kl4d4 / costheta_i * S2(costhet    
183                Fmu(k2, theta_i, theta_o, phi_o    
184                                                   
185       if (Intens > *max) {                        
186         *max = Intens;                            
187         max_theta_o = theta_o;                    
188         max_phi_o = phi_o;                        
189       }                                           
190                                                   
191       // Adds the newly found probability to t    
192                                                   
193       wkeit += Intens * ang_steptheta * ang_st    
194     }                                             
195   }                                               
196                                                   
197   // Fine-Iteration to find maximum of distrib    
198   // only if the energy is not zero               
199                                                   
200   if (E > 1e-10 * eV) {                           
201     // Break-condition for refining               
202                                                   
203     // Loop checking, 07-Aug-2015, Vladimir Iv    
204     while ((ang_stepphi >= AngCut * AngCut) ||    
205       a_max_theta_o = max_theta_o;                
206       a_max_phi_o = max_phi_o;                    
207       ang_stepphi /= 2.;                          
208       ang_steptheta /= 2.;                        
209                                                   
210       for (theta_o = a_max_theta_o - ang_stept    
211            theta_o += ang_steptheta)              
212       {                                           
213         // G4cout << "theta_o: " << theta_o/de    
214         costheta_o_squared = std::cos(theta_o)    
215         for (phi_o = a_max_phi_o - ang_stepphi    
216              phi_o += ang_stepphi)                
217         {                                         
218           // G4cout << "phi_o: " << phi_o/degr    
219           Intens = kl4d4 / costheta_i * S2(cos    
220                    S2(costheta_o_squared, klk2    
221                    std::sin(theta_o);             
222           if (Intens > *max) {                    
223             *max = Intens;                        
224             max_theta_o = theta_o;                
225             max_phi_o = phi_o;                    
226           }                                       
227         }                                         
228       }                                           
229     }                                             
230   }                                               
231   return wkeit;                                   
232 }                                                 
233                                                   
234 //....oooOO0OOooo........oooOO0OOooo........oo    
235                                                   
236 G4double G4UCNMicroRoughnessHelper::IntIminus(    
237   G4int AngNoTheta, G4int AngNoPhi, G4double b    
238 {                                                 
239   G4double a_max_thetas_o, max_thetas_o = thet    
240   G4double a_max_phis_o, max_phis_o = 0.;         
241   G4double thetas_o;                              
242   G4double phis_o;                                
243   G4double IntensS;                               
244   G4double ang_steptheta = 180. * degree / (An    
245   G4double ang_stepphi = 180. * degree / (AngN    
246   G4double costheta_i = std::cos(theta_i);        
247   G4double costheta_i_squared = costheta_i * c    
248                                                   
249   *max = 0.;                                      
250   G4double wkeit = 0.;                            
251                                                   
252   if (E < fermipot) {                             
253     return wkeit;                                 
254   }                                               
255                                                   
256   // k_l^4/4                                      
257   G4double kl4d4 =                                
258     neutron_mass_c2 / hbarc_squared * neutron_    
259   // (k_l/k)^2                                    
260   G4double klk2 = fermipot / E;                   
261                                                   
262   // (k_l/k')^2                                   
263   G4double klks2 = fermipot / (E - fermipot);     
264                                                   
265   // k'/k                                         
266   G4double ksdk = std::sqrt((E - fermipot) / E    
267                                                   
268   G4double costhetas_o_squared;                   
269                                                   
270   // k                                            
271   G4double k = std::sqrt(2 * neutron_mass_c2 *    
272                                                   
273   // k'                                           
274   G4double kS = ksdk * k;                         
275                                                   
276   for (thetas_o = 0. * degree; thetas_o <= 90.    
277     costhetas_o_squared = std::cos(thetas_o) *    
278                                                   
279     for (phis_o = -180. * degree; phis_o <= 18    
280       // cf. Steyerl-paper p. 176, eq. 21         
281       if (costhetas_o_squared >= -klks2) {        
282         // calculates probability for a certai    
283                                                   
284         G4double thetarefract = thetas_o;         
285         if (std::fabs(std::sin(theta_i) / ksdk    
286           thetarefract = std::asin(std::sin(th    
287         }                                         
288                                                   
289         IntensS = kl4d4 / costheta_i * ksdk *     
290                   SS2(costhetas_o_squared, klk    
291                   FmuS(k, kS, theta_i, thetas_    
292                   std::sin(thetas_o);             
293       }                                           
294       else {                                      
295         IntensS = 0.;                             
296       }                                           
297       // checks if the new probability is larg    
298       // the maximum found so far                 
299       if (IntensS > *max) {                       
300         *max = IntensS;                           
301       }                                           
302       wkeit += IntensS * ang_steptheta * ang_s    
303     }                                             
304   }                                               
305                                                   
306   // Fine-Iteration to find maximum of distrib    
307                                                   
308   if (E > 1e-10 * eV) {                           
309     // Break-condition for refining               
310                                                   
311     while (ang_stepphi >= AngCut * AngCut || a    
312       a_max_thetas_o = max_thetas_o;              
313       a_max_phis_o = max_phis_o;                  
314       ang_stepphi /= 2.;                          
315       ang_steptheta /= 2.;                        
316                                                   
317       for (thetas_o = a_max_thetas_o - ang_ste    
318            thetas_o <= a_max_thetas_o - ang_st    
319       {                                           
320         costhetas_o_squared = std::cos(thetas_    
321         for (phis_o = a_max_phis_o - ang_stepp    
322              phis_o += ang_stepphi)               
323         {                                         
324           G4double thetarefract = thetas_o;       
325           if (std::fabs(std::sin(theta_i) / ks    
326             thetarefract = std::asin(std::sin(    
327           }                                       
328                                                   
329           IntensS = kl4d4 / costheta_i * ksdk     
330                     SS2(costhetas_o_squared, k    
331                     FmuS(k, kS, theta_i, theta    
332                     std::sin(thetas_o);           
333           if (IntensS > *max) {                   
334             *max = IntensS;                       
335             max_thetas_o = thetas_o;              
336             max_phis_o = phis_o;                  
337           }                                       
338         }                                         
339       }                                           
340     }                                             
341   }                                               
342   return wkeit;                                   
343 }                                                 
344                                                   
345 //....oooOO0OOooo........oooOO0OOooo........oo    
346                                                   
347 G4double G4UCNMicroRoughnessHelper::ProbIplus(    
348   G4double theta_o, G4double phi_o, G4double b    
349 {                                                 
350   // k_l^4/4                                      
351   G4double kl4d4 =                                
352     neutron_mass_c2 / hbarc_squared * neutron_    
353                                                   
354   // (k_l/k)^2                                    
355   G4double klk2 = fermipot / E;                   
356                                                   
357   G4double costheta_i = std::cos(theta_i);        
358   G4double costheta_o = std::cos(theta_o);        
359                                                   
360   // eq. 20 on page 176 in the steyerl paper      
361                                                   
362   return kl4d4 / costheta_i * S2(costheta_i *     
363          S2(costheta_o * costheta_o, klk2) *      
364          Fmu(                                     
365            2 * neutron_mass_c2 * E / hbarc_squ    
366          std::sin(theta_o);                       
367 }                                                 
368                                                   
369 //....oooOO0OOooo........oooOO0OOooo........oo    
370                                                   
371 G4double G4UCNMicroRoughnessHelper::ProbIminus    
372   G4double thetas_o, G4double phis_o, G4double    
373 {                                                 
374   // k_l^4/4                                      
375   G4double kl4d4 =                                
376     neutron_mass_c2 / hbarc_squared * neutron_    
377   // (k_l/k)^2                                    
378   G4double klk2 = fermipot / E;                   
379                                                   
380   // (k_l/k')^2                                   
381   G4double klks2 = fermipot / (E - fermipot);     
382                                                   
383   if (E < fermipot) {                             
384     G4cout << " ProbIminus E < fermipot " << G    
385     return 0.;                                    
386   }                                               
387                                                   
388   // k'/k                                         
389   G4double ksdk = std::sqrt((E - fermipot) / E    
390                                                   
391   // k                                            
392   G4double k = std::sqrt(2 * neutron_mass_c2 *    
393                                                   
394   // k'/k                                         
395   G4double kS = ksdk * k;                         
396                                                   
397   G4double costheta_i = std::cos(theta_i);        
398   G4double costhetas_o = std::cos(thetas_o);      
399                                                   
400   // eq. 20 on page 176 in the steyerl paper      
401                                                   
402   G4double thetarefract = thetas_o;               
403   if (std::fabs(std::sin(theta_i) / ksdk) <= 1    
404     thetarefract = std::asin(std::sin(theta_i)    
405   }                                               
406                                                   
407   return kl4d4 / costheta_i * ksdk * S2(costhe    
408          SS2(costhetas_o * costhetas_o, klks2)    
409          FmuS(k, kS, theta_i, thetas_o, phis_o    
410          std::sin(thetas_o);                      
411 }                                                 
412