// SigmaEW.h is a part of the PYTHIA event generator. // Copyright (C) 2017 Torbjorn Sjostrand. // PYTHIA is licenced under the GNU GPL version 2, see COPYING for details. // Please respect the MCnet Guidelines, see GUIDELINES for details. // Header file for electroweak process differential cross sections. // Contains classes derived from SigmaProcess via Sigma(1/2)Process. #ifndef Pythia8_SigmaEW_H #define Pythia8_SigmaEW_H #include "Pythia8/PythiaComplex.h" #include "Pythia8/SigmaProcess.h" namespace Pythia8 { //========================================================================== // A derived class for q g -> q gamma (q = u, d, s, c, b). // Use massless approximation also for Q since no alternative. class Sigma2qg2qgamma : public Sigma2Process { public: // Constructor. Sigma2qg2qgamma() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "q g -> q gamma (udscb)";} virtual int code() const {return 201;} virtual string inFlux() const {return "qg";} private: // Values stored for later use. double sigUS, sigma0; }; //========================================================================== // A derived class for q qbar -> g gamma. class Sigma2qqbar2ggamma : public Sigma2Process { public: // Constructor. Sigma2qqbar2ggamma() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "q qbar -> g gamma";} virtual int code() const {return 202;} virtual string inFlux() const {return "qqbarSame";} private: // Values stored for later use. double sigma0; }; //========================================================================== // A derived class for g g -> g gamma. class Sigma2gg2ggamma : public Sigma2Process { public: // Constructor. Sigma2gg2ggamma() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "g g -> g gamma";} virtual int code() const {return 203;} virtual string inFlux() const {return "gg";} private: // Values stored for later use. double chargeSum, sigma; }; //========================================================================== // A derived class for f fbar -> gamma gamma. class Sigma2ffbar2gammagamma : public Sigma2Process { public: // Constructor. Sigma2ffbar2gammagamma() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f fbar -> gamma gamma";} virtual int code() const {return 204;} virtual string inFlux() const {return "ffbarSame";} private: // Values stored for later use. double sigTU, sigma0; }; //========================================================================== // A derived class for g g -> gamma gamma. class Sigma2gg2gammagamma : public Sigma2Process { public: // Constructor. Sigma2gg2gammagamma() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "g g -> gamma gamma";} virtual int code() const {return 205;} virtual string inFlux() const {return "gg";} private: double charge2Sum, sigma; }; //========================================================================== // A derived class for f f' -> f f' via t-channel gamma*/Z0 exchange. class Sigma2ff2fftgmZ : public Sigma2Process { public: // Constructor. Sigma2ff2fftgmZ() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f f' -> f f' (t-channel gamma*/Z0)";} virtual int code() const {return 211;} virtual string inFlux() const {return "ff";} private: // Z parameters for propagator. int gmZmode; double mZ, mZS, thetaWRat, sigmagmgm, sigmagmZ, sigmaZZ; }; //========================================================================== // A derived class for f_1 f_2 -> f_3 f_4 via t-channel W+- exchange. class Sigma2ff2fftW : public Sigma2Process { public: // Constructor. Sigma2ff2fftW() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f_1 f_2 -> f_3 f_4 (t-channel W+-)";} virtual int code() const {return 212;} virtual string inFlux() const {return "ff";} private: // W parameters for propagator. double mW, mWS, thetaWRat, sigma0; }; //========================================================================== // A derived class for q q' -> Q q" via t-channel W+- exchange. // Related to Sigma2ff2fftW class, but with massive matrix elements. class Sigma2qq2QqtW : public Sigma2Process { public: // Constructor. Sigma2qq2QqtW(int idIn, int codeIn) : idNew(idIn), codeSave(codeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for W decay angles in top decay (else inactive). virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return "ff";} virtual int id3Mass() const {return idNew;} private: // Values stored for process type. W parameters for propagator. int idNew, codeSave; string nameSave; double mW, mWS, thetaWRat, sigma0, openFracPos, openFracNeg; }; //========================================================================== // A derived class for f fbar -> gamma*/Z0. class Sigma1ffbar2gmZ : public Sigma1Process { public: // Constructor. Sigma1ffbar2gmZ() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for Z decay angle. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar -> gamma*/Z0";} virtual int code() const {return 221;} virtual string inFlux() const {return "ffbarSame";} virtual int resonanceA() const {return 23;} private: // Parameters set at initialization or for each new event. int gmZmode; double mRes, GammaRes, m2Res, GamMRat, thetaWRat, gamSum, intSum, resSum, gamProp, intProp, resProp; // Pointer to properties of the particle species, to access decay channels. ParticleDataEntry* particlePtr; }; //========================================================================== // A derived class for f fbar' -> W+-. class Sigma1ffbar2W : public Sigma1Process { public: // Constructor. Sigma1ffbar2W() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for W decay angle. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar' -> W+-";} virtual int code() const {return 222;} virtual string inFlux() const {return "ffbarChg";} virtual int resonanceA() const {return 24;} private: // Parameters set at initialization. double mRes, GammaRes, m2Res, GamMRat, thetaWRat, sigma0Pos, sigma0Neg; // Pointer to properties of the particle species, to access decay channels. ParticleDataEntry* particlePtr; }; //========================================================================== // A derived class for f fbar -> gamma* -> f' fbar', summed over light f'. // Allows pT-ordered evolution for multiparton interactions. class Sigma2ffbar2ffbarsgm : public Sigma2Process { public: // Constructor. Sigma2ffbar2ffbarsgm() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const { return "f fbar -> f' fbar' (s-channel gamma*)";} virtual int code() const {return 223;} virtual string inFlux() const {return "ffbarSame";} virtual bool isSChannel() const {return true;} private: // Values stored for later use. int idNew; double sigma0; }; //========================================================================== // A derived class for f fbar -> gamma*/Z0 -> f' fbar', summed over light f. class Sigma2ffbar2ffbarsgmZ : public Sigma2Process { public: // Constructor. Sigma2ffbar2ffbarsgmZ() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const { return "f fbar -> f' fbar' (s-channel gamma*/Z0)";} virtual int code() const {return 224;} virtual string inFlux() const {return "ffbarSame";} virtual bool isSChannel() const {return true;} virtual int idSChannel() const {return 23;} virtual int resonanceA() const {return 23;} private: // Parameters set at initialization or for each new event. int gmZmode; double mRes, GammaRes, m2Res, GamMRat, thetaWRat, colQ, gamSumT, gamSumL, intSumT, intSumL, intSumA, resSumT, resSumL, resSumA, gamProp, intProp, resProp, cThe; vector idVec; vector gamT, gamL, intT, intL, intA, resT, resL, resA, sigTLA; // Pointer to properties of the particle species, to access decay channels. ParticleDataEntry* particlePtr; }; //========================================================================== // A derived class for f_1 fbar_2 -> W+- -> f_3 fbar_4, summed over light f. class Sigma2ffbar2ffbarsW : public Sigma2Process { public: // Constructor. Sigma2ffbar2ffbarsW() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const { return "f_1 fbar_2 -> f_3 fbar_4 (s-channel W+-)";} virtual int code() const {return 225;} virtual string inFlux() const {return "ffbarChg";} virtual bool isSChannel() const {return true;} virtual int idSChannel() const {return 24;} virtual int resonanceA() const {return 24;} private: // Parameters set at initialization or stored for later use. int id3New, id4New; double mRes, GammaRes, m2Res, GamMRat, thetaWRat, sigma0; // Pointer to properties of the particle species, to access decay channels. ParticleDataEntry* particlePtr; }; //========================================================================== // A derived class for f fbar -> gamma*/Z0 -> F Fbar, for one heavy F. // Allows pT cuts as for other 2 -> 2 processes. class Sigma2ffbar2FFbarsgmZ : public Sigma2Process { public: // Constructor. Sigma2ffbar2FFbarsgmZ(int idIn, int codeIn) : idNew(idIn), codeSave(codeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for W decay angles in top decay (else inactive). virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return "ffbarSame";} virtual bool isSChannel() const {return true;} virtual int id3Mass() const {return idNew;} virtual int id4Mass() const {return idNew;} virtual int resonanceA() const {return 23;} private: // Values stored for process type. Z parameters for propagator. int idNew, codeSave, gmZmode; string nameSave; bool isPhysical; double ef, vf, af, mRes, GammaRes, m2Res, GamMRat, thetaWRat, mr, betaf, cosThe, gamProp, intProp, resProp, openFracPair; }; //========================================================================== // A derived class for f fbar' -> W+- -> F fbar", for one or two heavy F. // Allows pT cuts as for other 2 -> 2 processes. class Sigma2ffbar2FfbarsW : public Sigma2Process { public: // Constructor. Sigma2ffbar2FfbarsW(int idIn, int idIn2, int codeIn) : idNew(idIn), idNew2(idIn2), codeSave(codeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for W decay angles in top decay (else inactive). virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return "ffbarChg";} virtual bool isSChannel() const {return true;} virtual int id3Mass() const {return idNew;} virtual int id4Mass() const {return idPartner;} virtual int resonanceA() const {return 24;} private: // Values stored for process type. W parameters for propagator. int idNew, idNew2, codeSave, idPartner; string nameSave; bool isPhysical; double V2New, mRes, GammaRes, m2Res, GamMRat, thetaWRat, sigma0, openFracPos, openFracNeg; }; //========================================================================== // An intermediate class for f fbar -> gamma*/Z0/W+- gamma*/Z0/W-+. class Sigma2ffbargmZWgmZW : public Sigma2Process { public: // Constructor. Sigma2ffbargmZWgmZW() {} protected: // Internal products. Vec4 pRot[7]; complex hA[7][7]; complex hC[7][7]; // Calculate and store internal products. void setupProd( Event& process, int i1, int i2, int i3, int i4, int i5, int i6); // Evaluate the F function of Gunion and Kunszt. complex fGK(int i1, int i2, int i3, int i4, int i5, int i6); // Evaluate the Xi function of Gunion and Kunszt. double xiGK( double tHnow, double uHnow); // Evaluate the Xj function of Gunion and Kunszt. double xjGK( double tHnow, double uHnow); private: }; //========================================================================== // A derived class for f fbar -> gamma*/Z0 gamma*/Z0. class Sigma2ffbar2gmZgmZ : public Sigma2ffbargmZWgmZW { public: // Constructor. Sigma2ffbar2gmZgmZ() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for simultaneous flavour choices. virtual double weightDecayFlav( Event& process); // Evaluate weight for decay angles of the two gamma*/Z0. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar -> gamma*/Z0 gamma*/Z0";} virtual int code() const {return 231;} virtual string inFlux() const {return "ffbarSame";} virtual int id3Mass() const {return 23;} virtual int id4Mass() const {return 23;} private: // Parameters set at initialization or for each new event. int gmZmode, i1, i2, i3, i4, i5, i6; double mRes, GammaRes, m2Res, GamMRat, thetaWRat, sigma0, gamSum3, intSum3, resSum3, gamProp3, intProp3, resProp3, gamSum4, intSum4, resSum4, gamProp4, intProp4, resProp4, c3LL, c3LR, c3RL, c3RR, c4LL, c4LR, c4RL, c4RR, flavWt; // Pointer to properties of the particle species, to access decay channels. ParticleDataEntry* particlePtr; }; //========================================================================== // A derived class for f fbar' -> Z0 W+-. (Here pure Z0, unfortunately.) class Sigma2ffbar2ZW : public Sigma2ffbargmZWgmZW { public: // Constructor. Sigma2ffbar2ZW() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for Z0 and W+- decay angles. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar' -> Z0 W+- (no gamma*!)";} virtual int code() const {return 232;} virtual string inFlux() const {return "ffbarChg";} virtual int id3Mass() const {return 23;} virtual int id4Mass() const {return 24;} virtual int resonanceA() const {return 24;} private: // Store W+- mass and width, and couplings. double mW, widW, mWS, mwWS, sin2thetaW, cos2thetaW, thetaWRat, cotT, thetaWpt, thetaWmm, lun, lde, sigma0, openFracPos, openFracNeg; }; //========================================================================== // A derived class for f fbar -> W+ W-. class Sigma2ffbar2WW : public Sigma2ffbargmZWgmZW { public: // Constructor. Sigma2ffbar2WW() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for W+ and W- decay angles. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar -> W+ W-";} virtual int code() const {return 233;} virtual string inFlux() const {return "ffbarSame";} virtual int id3Mass() const {return 24;} virtual int id4Mass() const {return -24;} virtual int resonanceA() const {return 23;} private: // Store Z0 mass and width. double mZ, widZ, mZS, mwZS, thetaWRat, sigma0, cgg, cgZ, cZZ, cfg, cfZ, cff, gSS, gTT, gST, gUU, gSU, openFracPair; }; //========================================================================== // An intermediate class for f fbar -> gamma*/Z0 g/gamma and permutations. class Sigma2ffbargmZggm : public Sigma2Process { public: // Constructor. Sigma2ffbargmZggm() {} // Initialize process. virtual void initProc(); // Evaluate weight for gamma&/Z0 decay angle. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); protected: // Parameters set at initialization or for each new event. int gmZmode; double mRes, GammaRes, m2Res, GamMRat, thetaWRat, gamSum, intSum, resSum, gamProp, intProp, resProp; // Evaluate current sum of flavour couplings times phase space. void flavSum(); // Evaluate current propagator terms of cross section. void propTerm(); private: // Pointer to properties of the particle species, to access decay channels. ParticleDataEntry* particlePtr; }; //========================================================================== // A derived class for q qbar -> gamma*/Z0 g. class Sigma2qqbar2gmZg : public Sigma2ffbargmZggm { public: // Constructor. Sigma2qqbar2gmZg() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "q qbar -> gamma*/Z0 g";} virtual int code() const {return 241;} virtual string inFlux() const {return "qqbarSame";} virtual int id3Mass() const {return 23;} private: // Values stored for later use. double sigma0; }; //========================================================================== // A derived class for q g -> gamma*/Z0 q. class Sigma2qg2gmZq : public Sigma2ffbargmZggm { public: // Constructor. Sigma2qg2gmZq() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "q g-> gamma*/Z0 q";} virtual int code() const {return 242;} virtual string inFlux() const {return "qg";} virtual int id3Mass() const {return 23;} private: // Values stored for later use. double sigma0; }; //========================================================================== // A derived class for f fbar' -> gamma*/Z0 gamma. class Sigma2ffbar2gmZgm : public Sigma2ffbargmZggm { public: // Constructor. Sigma2ffbar2gmZgm() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f fbar -> gamma*/Z0 gamma";} virtual int code() const {return 243;} virtual string inFlux() const {return "ffbarSame";} virtual int id3Mass() const {return 23;} private: // Values stored for later use. double sigma0; }; //========================================================================== // A derived class for f gamma -> gamma*/Z0 f. class Sigma2fgm2gmZf : public Sigma2ffbargmZggm { public: // Constructor. Sigma2fgm2gmZf() {} // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f gamma -> gamma*/Z0 f";} virtual int code() const {return 244;} virtual string inFlux() const {return "fgm";} virtual int id3Mass() const {return 23;} private: // Values stored for later use. double sigma0; }; //========================================================================== // An intermediate class for f fbar -> W+- g/gamma and permutations. class Sigma2ffbarWggm : public Sigma2Process { public: // Constructor. Sigma2ffbarWggm() {} // Evaluate weight for gamma&/Z0 decay angle. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); private: }; //========================================================================== // A derived class for q qbar' -> W+- g. class Sigma2qqbar2Wg : public Sigma2ffbarWggm { public: // Constructor. Sigma2qqbar2Wg() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "q qbar' -> W+- g";} virtual int code() const {return 251;} virtual string inFlux() const {return "ffbarChg";} virtual int id3Mass() const {return 24;} private: // Values stored for later use. double sigma0, openFracPos, openFracNeg; }; //========================================================================== // A derived class for q g -> W+- q'. class Sigma2qg2Wq : public Sigma2ffbarWggm { public: // Constructor. Sigma2qg2Wq() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "q g-> W+- q'";} virtual int code() const {return 252;} virtual string inFlux() const {return "qg";} virtual int id3Mass() const {return 24;} private: // Values stored for later use. double sigma0, openFracPos, openFracNeg; }; //========================================================================== // A derived class for f fbar' -> W+- gamma. class Sigma2ffbar2Wgm : public Sigma2ffbarWggm { public: // Constructor. Sigma2ffbar2Wgm() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f fbar' -> W+- gamma";} virtual int code() const {return 253;} virtual string inFlux() const {return "ffbarChg";} virtual int id3Mass() const {return 24;} private: // Values stored for later use. double sigma0, openFracPos, openFracNeg; }; //========================================================================== // A derived class for f gamma -> W+- f'. class Sigma2fgm2Wf : public Sigma2ffbarWggm { public: // Constructor. Sigma2fgm2Wf() {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return "f gamma -> W+- f'";} virtual int code() const {return 254;} virtual string inFlux() const {return "fgm";} virtual int id3Mass() const {return 24;} private: // Values stored for later use. double sigma0, openFracPos, openFracNeg; }; //========================================================================== // A derived class for gamma gamma -> f fbar. class Sigma2gmgm2ffbar : public Sigma2Process { public: // Constructor. Sigma2gmgm2ffbar(int idIn, int codeIn) : idNew(idIn), codeSave(codeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return "gmgm";} virtual int id3Mass() const {return idMass;} virtual int id4Mass() const {return idMass;} private: // Member variables. int idNew, codeSave, idMass, idNow; string nameSave; double ef4, s34Avg, sigTU, sigma, openFracPair; }; //========================================================================== // A derived class for g gamma -> q qbar (q = u, d, s, c, b). class Sigma2ggm2qqbar : public Sigma2Process { public: // Constructor. Sigma2ggm2qqbar(int idIn, int codeIn, string inFluxIn = "ggm") : idNew(idIn), codeSave(codeIn), inFluxSave(inFluxIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return inFluxSave;} virtual int id3Mass() const {return idMass;} virtual int id4Mass() const {return idMass;} private: // Member variables. int idNew, codeSave, idMass, idNow; string nameSave, inFluxSave; double ef2, s34Avg, sigTU, sigma, openFracPair; }; //========================================================================== // A derived class for q gamma -> q g (q = u, d, s, c, b). // Use massless approximation also for Q since no alternative. class Sigma2qgm2qg : public Sigma2Process { public: // Constructor. Sigma2qgm2qg(int codeIn, string inFluxIn = "qgm") : codeSave(codeIn), inFluxSave(inFluxIn) {} // Initialize process according to in flux. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return inFluxSave;} private: // Values stored for later use. int codeSave; double sigUS, sigma0; string nameSave, inFluxSave; }; //========================================================================== // A derived class for q gamma -> q gamma (q = u, d, s, c, b). // Use massless approximation also for Q since no alternative. class Sigma2qgm2qgm : public Sigma2Process { public: // Constructor. Sigma2qgm2qgm(int codeIn, string inFluxIn = "qgm") : codeSave(codeIn), inFluxSave(inFluxIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate d(sigmaHat)/d(tHat). virtual double sigmaHat(); // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Info on the subprocess. virtual string name() const {return nameSave;} virtual int code() const {return codeSave;} virtual string inFlux() const {return inFluxSave;} private: // Values stored for later use. int codeSave; double sigUS, sigma0; string nameSave, inFluxSave; }; //========================================================================== } // end namespace Pythia8 #endif // Pythia8_SigmaEW_H