1 | // |
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2 | // ******************************************************************** |
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15 | // * use. Please see the license in the file LICENSE and URL above * |
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17 | // * * |
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18 | // * This code implementation is the result of the scientific and * |
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19 | // * technical work of the GEANT4 collaboration. * |
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24 | // ******************************************************************** |
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25 | // |
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26 | // $Id: G4TritonEvaporationProbability.cc,v 1.18 2010/11/17 11:06:03 vnivanch Exp $ |
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27 | // GEANT4 tag $Name: geant4-09-04-ref-00 $ |
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28 | // |
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29 | // J.M. Quesada (August2008). Based on: |
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30 | // |
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31 | // Hadronic Process: Nuclear De-excitations |
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32 | // by V. Lara (Oct 1998) |
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33 | // |
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34 | // Modified: |
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35 | // 03-09-2008 J.M. Quesada for external choice of inverse cross section option |
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36 | // 17-11-2010 V.Ivanchenko integer Z and A |
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37 | |
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38 | #include "G4TritonEvaporationProbability.hh" |
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39 | |
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40 | G4TritonEvaporationProbability::G4TritonEvaporationProbability() : |
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41 | G4EvaporationProbability(3,1,2,&theCoulombBarrier) // A,Z,Gamma,&theCoulombBarrier |
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42 | {} |
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43 | |
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44 | G4TritonEvaporationProbability::~G4TritonEvaporationProbability() |
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45 | {} |
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46 | |
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47 | G4double G4TritonEvaporationProbability::CalcAlphaParam(const G4Fragment & fragment) |
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48 | { |
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49 | return 1.0 + CCoeficient(fragment.GetZ_asInt()-GetZ()); |
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50 | } |
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51 | |
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52 | G4double G4TritonEvaporationProbability::CalcBetaParam(const G4Fragment & ) |
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53 | { |
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54 | return 0.0; |
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55 | } |
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56 | |
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57 | G4double G4TritonEvaporationProbability::CCoeficient(G4int aZ) |
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58 | { |
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59 | // Data comes from |
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60 | // Dostrovsky, Fraenkel and Friedlander |
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61 | // Physical Review, vol 116, num. 3 1959 |
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62 | // |
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63 | // const G4int size = 5; |
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64 | // G4double Zlist[5] = { 10.0, 20.0, 30.0, 50.0, 70.0}; |
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65 | // G4double Cp[5] = { 0.50, 0.28, 0.20, 0.15, 0.10}; |
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66 | // C for triton is equal to C for protons divided by 3 |
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67 | G4double C = 0.0; |
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68 | |
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69 | if (aZ >= 70) { |
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70 | C = 0.10; |
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71 | } else { |
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72 | C = ((((0.15417e-06*aZ) - 0.29875e-04)*aZ + 0.21071e-02)*aZ - 0.66612e-01)*aZ + 0.98375; |
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73 | } |
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74 | |
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75 | return C/3.0; |
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76 | } |
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77 | |
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78 | /////////////////////////////////////////////////////////////////////////////////// |
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79 | //J. M. Quesada (Dec 2007-June 2008): New inverse reaction cross sections |
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80 | //OPT=0 Dostrovski's parameterization |
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81 | //OPT=1,2 Chatterjee's paramaterization |
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82 | //OPT=3,4 Kalbach's parameterization |
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83 | // |
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84 | G4double |
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85 | G4TritonEvaporationProbability::CrossSection(const G4Fragment & fragment, G4double K) |
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86 | { |
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87 | theA=GetA(); |
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88 | theZ=GetZ(); |
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89 | ResidualA=fragment.GetA_asInt()-theA; |
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90 | ResidualZ=fragment.GetZ_asInt()-theZ; |
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91 | |
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92 | ResidualAthrd=fG4pow->Z13(ResidualA); |
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93 | FragmentA=fragment.GetA_asInt(); |
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94 | FragmentAthrd=fG4pow->Z13(FragmentA); |
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95 | |
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96 | if (OPTxs==0) {std::ostringstream errOs; |
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97 | errOs << "We should'n be here (OPT =0) at evaporation cross section calculation (tritons)!!" |
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98 | <<G4endl; |
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99 | throw G4HadronicException(__FILE__, __LINE__, errOs.str()); |
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100 | return 0.;} |
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101 | if( OPTxs==1 || OPTxs==2) return G4TritonEvaporationProbability::GetOpt12( K); |
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102 | else if (OPTxs==3 || OPTxs==4) return G4TritonEvaporationProbability::GetOpt34( K); |
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103 | else{ |
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104 | std::ostringstream errOs; |
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105 | errOs << "BAD Triton CROSS SECTION OPTION AT EVAPORATION!!" <<G4endl; |
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106 | throw G4HadronicException(__FILE__, __LINE__, errOs.str()); |
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107 | return 0.; |
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108 | } |
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109 | } |
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110 | |
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111 | // |
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112 | //********************* OPT=1,2 : Chatterjee's cross section ***************** |
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113 | //(fitting to cross section from Bechetti & Greenles OM potential) |
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114 | |
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115 | G4double G4TritonEvaporationProbability::GetOpt12(G4double K) |
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116 | { |
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117 | G4double Kc=K; |
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118 | |
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119 | // JMQ xsec is set constat above limit of validity |
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120 | if (K > 50*MeV) { Kc=50*MeV; } |
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121 | |
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122 | G4double landa ,mu ,nu ,p , Ec,q,r,ji,xs; |
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123 | |
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124 | G4double p0 = -11.04; |
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125 | G4double p1 = 619.1; |
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126 | G4double p2 = -2147.; |
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127 | G4double landa0 = -0.0426; |
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128 | G4double landa1 = -10.33; |
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129 | G4double mu0 = 601.9; |
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130 | G4double mu1 = 0.37; |
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131 | G4double nu0 = 583.0; |
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132 | G4double nu1 = -546.2; |
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133 | G4double nu2 = 1.718; |
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134 | G4double delta=1.2; |
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135 | |
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136 | Ec = 1.44*theZ*ResidualZ/(1.5*ResidualAthrd+delta); |
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137 | p = p0 + p1/Ec + p2/(Ec*Ec); |
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138 | landa = landa0*ResidualA + landa1; |
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139 | |
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140 | G4double resmu1 = fG4pow->powZ(ResidualA,mu1); |
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141 | mu = mu0*resmu1; |
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142 | nu = resmu1*(nu0 + nu1*Ec + nu2*(Ec*Ec)); |
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143 | q = landa - nu/(Ec*Ec) - 2*p*Ec; |
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144 | r = mu + 2*nu/Ec + p*(Ec*Ec); |
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145 | |
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146 | ji=std::max(Kc,Ec); |
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147 | if(Kc < Ec) { xs = p*Kc*Kc + q*Kc + r;} |
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148 | else {xs = p*(Kc - ji)*(Kc - ji) + landa*Kc + mu + nu*(2 - Kc/ji)/ji ;} |
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149 | |
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150 | if (xs <0.0) {xs=0.0;} |
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151 | |
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152 | return xs; |
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153 | } |
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154 | |
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155 | // *********** OPT=3,4 : Kalbach's cross sections (from PRECO code)************* |
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156 | G4double G4TritonEvaporationProbability::GetOpt34(G4double K) |
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157 | // ** t from o.m. of hafele, flynn et al |
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158 | { |
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159 | G4double landa, mu, nu, p , signor(1.),sig; |
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160 | G4double ec,ecsq,xnulam,etest(0.),a; |
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161 | G4double b,ecut,cut,ecut2,geom,elab; |
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162 | |
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163 | G4double flow = 1.e-18; |
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164 | G4double spill= 1.e+18; |
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165 | |
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166 | G4double p0 = -21.45; |
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167 | G4double p1 = 484.7; |
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168 | G4double p2 = -1608.; |
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169 | G4double landa0 = 0.0186; |
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170 | G4double landa1 = -8.90; |
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171 | G4double mu0 = 686.3; |
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172 | G4double mu1 = 0.325; |
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173 | G4double nu0 = 368.9; |
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174 | G4double nu1 = -522.2; |
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175 | G4double nu2 = -4.998; |
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176 | |
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177 | G4double ra=0.80; |
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178 | |
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179 | //JMQ 13/02/09 increase of reduced radius to lower the barrier |
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180 | // ec = 1.44 * theZ * ResidualZ / (1.5*ResidualAthrd+ra); |
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181 | ec = 1.44 * theZ * ResidualZ / (1.7*ResidualAthrd+ra); |
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182 | ecsq = ec * ec; |
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183 | p = p0 + p1/ec + p2/ecsq; |
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184 | landa = landa0*ResidualA + landa1; |
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185 | a = fG4pow->powZ(ResidualA,mu1); |
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186 | mu = mu0 * a; |
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187 | nu = a* (nu0+nu1*ec+nu2*ecsq); |
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188 | xnulam = nu / landa; |
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189 | if (xnulam > spill) { xnulam=0.; } |
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190 | if (xnulam >= flow) { etest = 1.2 *std::sqrt(xnulam); } |
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191 | |
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192 | a = -2.*p*ec + landa - nu/ecsq; |
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193 | b = p*ecsq + mu + 2.*nu/ec; |
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194 | ecut = 0.; |
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195 | cut = a*a - 4.*p*b; |
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196 | if (cut > 0.) { ecut = std::sqrt(cut); } |
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197 | ecut = (ecut-a) / (p+p); |
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198 | ecut2 = ecut; |
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199 | //JMQ 290310 for avoiding unphysical increase below minimum (at ecut) |
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200 | // ecut<0 means that there is no cut with energy axis, i.e. xs is set |
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201 | // to 0 bellow minimum |
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202 | // if (cut < 0.) ecut2 = ecut - 2.; |
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203 | if (cut < 0.) { ecut2 = ecut; } |
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204 | elab = K * FragmentA / G4double(ResidualA); |
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205 | sig = 0.; |
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206 | |
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207 | if (elab <= ec) { //start for E<Ec |
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208 | if (elab > ecut2) { sig = (p*elab*elab+a*elab+b) * signor; } |
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209 | } //end for E<Ec |
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210 | else { //start for E>Ec |
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211 | sig = (landa*elab+mu+nu/elab) * signor; |
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212 | geom = 0.; |
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213 | if (xnulam < flow || elab < etest) { return sig; } |
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214 | geom = std::sqrt(theA*K); |
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215 | geom = 1.23*ResidualAthrd + ra + 4.573/geom; |
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216 | geom = 31.416 * geom * geom; |
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217 | sig = std::max(geom,sig); |
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218 | } //end for E>Ec |
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219 | return sig; |
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220 | } |
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221 | |
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