G4PolarizedBhabhaCrossSection Class Reference

#include <G4PolarizedBhabhaCrossSection.hh>

Inheritance diagram for G4PolarizedBhabhaCrossSection:

Collaboration diagram for G4PolarizedBhabhaCrossSection:

Public Member Functions
	G4PolarizedBhabhaCrossSection ()
virtual	~G4PolarizedBhabhaCrossSection ()
void	Initialize (G4double x, G4double y, G4double phi, const G4StokesVector &p0, const G4StokesVector &p1, G4int flag=0) override
G4double	XSection (const G4StokesVector &pol2, const G4StokesVector &pol3) override
G4double	TotalXSection (G4double xmin, G4double xmax, G4double y, const G4StokesVector &pol0, const G4StokesVector &pol1) override
G4StokesVector	GetPol2 () override
G4StokesVector	GetPol3 () override
Public Member Functions inherited from G4VPolarizedCrossSection
	G4VPolarizedCrossSection ()
virtual	~G4VPolarizedCrossSection ()
G4double	GetYmin ()
virtual G4double	GetXmin (G4double y)
virtual G4double	GetXmax (G4double y)
void	SetMaterial (G4double A, G4double Z, G4double coul)

Additional Inherited Members
Protected Member Functions inherited from G4VPolarizedCrossSection
void	SetXmin (G4double xmin)
void	SetXmax (G4double xmax)
void	SetYmin (G4double ymin)
Protected Attributes inherited from G4VPolarizedCrossSection
G4double	fXmin
G4double	fXmax
G4double	fYmin
G4double	theA
G4double	theZ
G4double	fCoul

Detailed Description

Definition at line 52 of file G4PolarizedBhabhaCrossSection.hh.

Constructor & Destructor Documentation

G4PolarizedBhabhaCrossSection::G4PolarizedBhabhaCrossSection

(

)

Definition at line 56 of file G4PolarizedBhabhaCrossSection.cc.

                                                             : phi0(1.)
{
}

G4PolarizedBhabhaCrossSection::~G4PolarizedBhabhaCrossSection ( )

virtual

Definition at line 59 of file G4PolarizedBhabhaCrossSection.cc.

{
}

Member Function Documentation

G4StokesVector G4PolarizedBhabhaCrossSection::GetPol2 ( )

overridevirtual

Reimplemented from G4VPolarizedCrossSection.

Definition at line 298 of file G4PolarizedBhabhaCrossSection.cc.

{
  // Note, mean polarization can not contain correlation
  // effects.
  return  1./phi0 * phi2;
}

G4StokesVector G4PolarizedBhabhaCrossSection::GetPol3 ( )

overridevirtual

Reimplemented from G4VPolarizedCrossSection.

Definition at line 304 of file G4PolarizedBhabhaCrossSection.cc.

{
  // Note, mean polarization can not contain correlation
  // effects.
  return  1./phi0 * phi3;
}

void G4PolarizedBhabhaCrossSection::Initialize ( G4double  x, G4double  y, G4double  phi, const G4StokesVector &  p0, const G4StokesVector &  p1, G4int  flag = 0  )

overridevirtual

Reimplemented from G4VPolarizedCrossSection.

Definition at line 62 of file G4PolarizedBhabhaCrossSection.cc.

{
  SetXmax(1.);

  G4double re2 = classic_electr_radius * classic_electr_radius;
  G4double gamma2 = gamma*gamma;
  G4double gamma3 = gamma2*gamma;
  G4double gmo = (gamma - 1.);
  G4double gmo2 = (gamma - 1.)*(gamma - 1.);
  G4double gmo3 = gmo2*(gamma - 1.);
  G4double gpo = (gamma + 1.);
  G4double gpo2 = (gamma + 1.)*(gamma + 1.);
  G4double gpo3 = gpo2*(gamma + 1.);
  G4double gpo12 = std::sqrt(gpo);
  G4double gpo32 = gpo*gpo12;
  G4double gpo52 = gpo2*gpo12;

  G4double pref = re2/(gamma - 1.0);
  G4double sqrttwo=std::sqrt(2.);
  G4double d = std::sqrt(1./e - 1.);
  G4double e2 = e*e;
  G4double e3 = e2*e;

  // *** new ***
  G4double gmo12 = std::sqrt(gmo);
  G4double gmo32 = gmo*gmo12;
  G4double egmp32 = std::pow(e*(2 + e*gmo)*gpo,(3./2.));
  G4double e32 = e*std::sqrt(e);

  G4bool polarized=(!pol0.IsZero())||(!pol1.IsZero());

  if (flag==0) polarized=false;
  // Unpolarised part of XS
  // *AS* UnpME . OK 
  phi0 = 0.;
  phi0+= e2*gmo3/gpo3;
  phi0+= -2.*e*gamma*gmo2/gpo3;
  phi0+= (3.*gamma2 + 6.*gamma + 4.)*gmo/gpo3;
  phi0+= -(2.*gamma2 + 4.*gamma + 1.)/(e*gpo2);
  phi0+= gamma2/(e2*(gamma2 - 1.));
  phi0*=0.25;
  // Initial state polarisarion dependence
  if (polarized) {
    //    G4cout<<"Polarized differential Bhabha cross section"<<G4endl;
    //    G4cout<<"Initial state polarisation contributions"<<G4endl;
    //    G4cout<<"Diagonal Matrix Elements"<<G4endl;
    // *** new ***
    G4double xx = -((e*gmo - gamma)*(-1 - gamma + e*(e*gmo - gamma)*(3 + gamma)))/(4*e*gpo3);
    G4double yy = (e3*gmo3 - 2*e2*gmo2*gamma - gpo*(1 + 2*gamma) + e*(-2 + gamma2 + gamma3))/(4*e*gpo3);
    G4double zz = ((e*gmo - gamma)*(e2*gmo*(3 + gamma) - e*gamma*(3 + gamma) + gpo*(1 + 2*gamma)))/(4*e*gpo3);
    // ***

    phi0 += xx*pol0.x()*pol1.x() + yy*pol0.y()*pol1.y() + zz*pol0.z()*pol1.z();

    {
      G4double xy = 0;
      G4double xz = (d*(e*gmo - gamma)*(-1 + 2*e*gmo - gamma))/(2*sqrttwo*gpo52);
      G4double yx = 0;
      G4double yz = 0;
      G4double zx = xz;
      G4double zy = 0;
    //    G4cout<<"Non-diagonal Matrix Elements"<<G4endl;
      phi0+=yx*pol0.y()*pol1.x() + xy*pol0.x()*pol1.y();
      phi0+=zx*pol0.z()*pol1.x() + xz*pol0.x()*pol1.z();
      phi0+=zy*pol0.z()*pol1.y() + yz*pol0.y()*pol1.z();
    }
  }
  // Final state polarisarion dependence
  phi2=G4ThreeVector();
  phi3=G4ThreeVector();

  if (flag>=1) {
    //
    // Final Positron Ppl
    //
    // initial positron Kpl
    if (!pol0.IsZero()) {

      G4double xxPplKpl = -((-1 + e)*(e*gmo - gamma)*(-(gamma*gpo) +  e*(-2 + gamma + gamma2)))/
    (4*e2*gpo*std::sqrt(gmo*gpo*(-1 + e + gamma - e*gamma)*  (1 + e + gamma - e*gamma)));
      G4double xyPplKpl = 0;
      G4double xzPplKpl = ((e*gmo - gamma)*(-1 - gamma + e*gmo*(1 + 2*gamma)))/
    (2*sqrttwo*e32*gmo*gpo2*std::sqrt(1 + e + gamma - e*gamma));
      G4double yxPplKpl = 0;
      G4double yyPplKpl = (gamma2*gpo + e2*gmo2*(3 + gamma) - 
          e*gmo*(1 + 2*gamma*(2 + gamma)))/(4*e2*gmo*gpo2);
      G4double yzPplKpl = 0;
      G4double zxPplKpl = ((e*gmo - gamma)*(1 + e*(-1 + 2*e*gmo - 2*gamma)*gmo + gamma))/
    (2*sqrttwo*e*gmo*gpo2*std::sqrt(e*(1 + e + gamma - e*gamma)));
      G4double zyPplKpl = 0;
      G4double zzPplKpl = -((e*gmo - gamma)*std::sqrt((1 - e)/(e - e*gamma2 + gpo2))*
           (2*e2*gmo2 + gamma + gamma2 - e*(-2 + gamma + gamma2)))/
    (4*e2*(-1 + gamma2));

      phi2[0] += xxPplKpl*pol0.x() + xyPplKpl*pol0.y() + xzPplKpl*pol0.z();
      phi2[1] += yxPplKpl*pol0.x() + yyPplKpl*pol0.y() + yzPplKpl*pol0.z();
      phi2[2] += zxPplKpl*pol0.x() + zyPplKpl*pol0.y() + zzPplKpl*pol0.z();
    }
    // initial electron Kmn
    if (!pol1.IsZero()) {
      G4double xxPplKmn = ((-1 + e)*(e*(-2 + gamma)*gmo + gamma))/(4*e*gpo32*std::sqrt(1 + e2*gmo + gamma - 2*e*gamma));
      G4double xyPplKmn = 0;
      G4double xzPplKmn = (-1 + e*gmo + gmo*gamma)/(2*sqrttwo*gpo2* std::sqrt(e*(1 + e + gamma - e*gamma)));
      G4double yxPplKmn = 0;
      G4double yyPplKmn = (-1 - 2*gamma + e*gmo*(3 + gamma))/(4*e*gpo2);
      G4double yzPplKmn = 0;
      G4double zxPplKmn = (1 + 2*e2*gmo2 + gamma + gamma2 + e*(1 + (3 - 4*gamma)*gamma))/
    (2*sqrttwo*gpo2*std::sqrt(e*(1 + e + gamma - e*gamma)));
      G4double zyPplKmn = 0;
      G4double zzPplKmn = -(std::sqrt((1 - e)/(e - e*gamma2 + gpo2))*
           (2*e2*gmo2 + gamma + 2*gamma2 + e*(2 + gamma - 3*gamma2)))/(4*e*gpo);

      phi2[0] += xxPplKmn*pol1.x() + xyPplKmn*pol1.y() + xzPplKmn*pol1.z();
      phi2[1] += yxPplKmn*pol1.x() + yyPplKmn*pol1.y() + yzPplKmn*pol1.z();
      phi2[2] += zxPplKmn*pol1.x() + zyPplKmn*pol1.y() + zzPplKmn*pol1.z();
    }
//
// Final Electron Pmn
//
    // initial positron Kpl
    if (!pol0.IsZero()) {
      G4double xxPmnKpl = ((-1 + e*gmo)*(2 + gamma))/(4*gpo* std::sqrt(e*(2 + e*gmo)*gpo));
      G4double xyPmnKpl = 0;
      G4double xzPmnKpl = (std::sqrt((-1 + e)/(-2 + e - e*gamma))*
        (e + gamma + e*gamma -   2*(-1 + e)*gamma2))/(2*sqrttwo*e*gpo2);
      G4double yxPmnKpl = 0;
      G4double yyPmnKpl = (-1 - 2*gamma + e*gmo*(3 + gamma))/(4*e*gpo2);
      G4double yzPmnKpl = 0;
      G4double zxPmnKpl = -((-1 + e)*(1 + 2*e*gmo)*(e*gmo - gamma))/
    (2*sqrttwo*e*std::sqrt(-((-1 + e)*(2 + e*gmo)))*gpo2);
      G4double zyPmnKpl = 0;
      G4double zzPmnKpl = (-2 + 2*e2*gmo2 + gamma*(-1 + 2*gamma) + 
          e*(-2 + (5 - 3*gamma)*gamma))/(4*std::sqrt(e*(2 + e*gmo))*  gpo32);

      phi3[0] += xxPmnKpl*pol0.x() + xyPmnKpl*pol0.y() + xzPmnKpl*pol0.z();
      phi3[1] += yxPmnKpl*pol0.x() + yyPmnKpl*pol0.y() + yzPmnKpl*pol0.z();
      phi3[2] += zxPmnKpl*pol0.x() + zyPmnKpl*pol0.y() + zzPmnKpl*pol0.z();
    }
    // initial electron Kmn
    if (!pol1.IsZero()) {
      G4double xxPmnKmn = -((2 + e*gmo)*(-1 + e*gmo - gamma)*(e*gmo - gamma)*
           (-2 + gamma))/(4*gmo*egmp32);
      G4double xyPmnKmn = 0;
      G4double xzPmnKmn = ((e*gmo - gamma)*
               std::sqrt((-1 + e + gamma - e*gamma)/(2 + e*gmo))*
               (e + gamma - e*gamma + gamma2))/
    (2*sqrttwo*e2*gmo32*gpo2);
      G4double yxPmnKmn = 0;
      G4double yyPmnKmn = (gamma2*gpo + e2*gmo2*(3 + gamma) - 
          e*gmo*(1 + 2*gamma*(2 + gamma)))/(4*e2*gmo*gpo2);
      G4double yzPmnKmn = 0;
      G4double zxPmnKmn = -((-1 + e)*(e*gmo - gamma)*(e*gmo + 2*e2*gmo2 - gamma*gpo))/
    (2*sqrttwo*e2*std::sqrt(-((-1 + e)*(2 + e*gmo)))* gmo*gpo2);
      G4double zyPmnKmn = 0;
      G4double zzPmnKmn = ((e*gmo - gamma)*std::sqrt(e/((2 + e*gmo)*gpo))*
          (-(e*(-2 + gamma)*gmo) + 2*e2*gmo2 + (-2 + gamma)*gpo))/(4*e2*(-1 + gamma2));

      phi3[0] += xxPmnKmn*pol1.x() + xyPmnKmn*pol1.y() + xzPmnKmn*pol1.z();
      phi3[1] += yxPmnKmn*pol1.x() + yyPmnKmn*pol1.y() + yzPmnKmn*pol1.z();
      phi3[2] += zxPmnKmn*pol1.x() + zyPmnKmn*pol1.y() + zzPmnKmn*pol1.z();
    }
  }
  phi0 *= pref;
  phi2 *= pref;
  phi3 *= pref;

}

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G4double G4PolarizedBhabhaCrossSection::TotalXSection ( G4double  xmin, G4double  xmax, G4double  y, const G4StokesVector &  pol0, const G4StokesVector &  pol1  )

overridevirtual

Reimplemented from G4VPolarizedCrossSection.

Definition at line 249 of file G4PolarizedBhabhaCrossSection.cc.

{
  G4double xs=0.;

  G4double x=xmin;

  if (xmax != 1.) G4cout<<" warning xmax expected to be 1 but is "<<xmax<< G4endl;

  //  re -> electron radius^2;
  G4double re2 = classic_electr_radius * classic_electr_radius;
  G4double gamma2=gamma*gamma;
  G4double gmo2 = (gamma - 1.)*(gamma - 1.);
  G4double gpo2 = (gamma + 1.)*(gamma + 1.);
  G4double gpo3 = gpo2*(gamma + 1.);
  G4double logMEM = std::log(x);
  G4double pref = twopi*re2/(gamma - 1.0);
  // unpolarise XS
  G4double sigma0 = 0.;
    sigma0 += -gmo2*(gamma - 1.)*x*x*x/3. + gmo2*gamma*x*x;
    sigma0 += -(gamma - 1.)*(3.*gamma*(gamma + 2.) +4.)*x;
    sigma0 += (gamma*(gamma*(gamma*(4.*gamma - 1.) - 21.) - 7.)+13.)/(3.*(gamma - 1.));
    sigma0 /= gpo3;
    sigma0 += logMEM*(2. - 1./gpo2);
    sigma0 += gamma2/((gamma2 - 1.)*x);
  //    longitudinal part
  G4double sigma2=0.;
    sigma2 += logMEM*gamma*(gamma + 1.)*(2.*gamma + 1.);
    sigma2 += gamma*(7.*gamma*(gamma + 1.) - 2.)/3.;
    sigma2 += -(3.*gamma + 1.)*(gamma2 + gamma - 1.)*x;
    sigma2 += (gamma - 1.)*gamma*(gamma + 3.)*x*x;
    sigma2 += -gmo2*(gamma + 3.)*x*x*x/3.;
    sigma2 /= gpo3;
  //    transverse part
  G4double sigma3=0.;
    sigma3 += 0.5*(gamma + 1.)*(3.*gamma + 1.)*logMEM;
    sigma3 += (gamma*(5.*gamma - 4.) - 13.)/6.;
    sigma3 += 0.5*(gamma2 + 3.)*x;
    sigma3 += - 2.*(gamma - 1.)*gamma*x*x;  // *AS* changed sign
    sigma3 += 2.*gmo2*x*x*x/3.;
    sigma3 /= gpo3;
  // total cross section
  xs+=pref*(sigma0 + sigma2*pol0.z()*pol1.z() + sigma3*(pol0.x()*pol1.x()+pol0.y()*pol1.y()));

  return xs;
}

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G4double G4PolarizedBhabhaCrossSection::XSection ( const G4StokesVector &  pol2, const G4StokesVector &  pol3  )

overridevirtual

Implements G4VPolarizedCrossSection.

Definition at line 236 of file G4PolarizedBhabhaCrossSection.cc.

{
  G4double xs=0.;
  xs+=phi0;

  G4bool polarized=(!pol2.IsZero())||(!pol3.IsZero());
  if (polarized) {
    xs+=phi2*pol2 + phi3*pol3;
  }
  return xs;
}

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---

The documentation for this class was generated from the following files:

• geant4.10.03.p01/source/processes/electromagnetic/polarisation/include/G4PolarizedBhabhaCrossSection.hh
• geant4.10.03.p01/source/processes/electromagnetic/polarisation/src/G4PolarizedBhabhaCrossSection.cc