// SigmaHiggs.h is a part of the PYTHIA event generator. // Copyright (C) 2012 Torbjorn Sjostrand. // Part of code written by Marc Montull, CERN summer student 2007. // 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 Higgs process differential cross sections. // Contains classes derived from SigmaProcess via Sigma2Process. #ifndef Pythia8_SigmaHiggs_H #define Pythia8_SigmaHiggs_H #include "SigmaProcess.h" namespace Pythia8 { //========================================================================== // A derived class for f fbar -> H0 (SM), H1, H2 or A3 (BSM). class Sigma1ffbar2H : public Sigma1Process { public: // Constructor. Sigma1ffbar2H(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 int resonanceA() const {return idRes;} private: // An H0, H1, H2 or A3 resonance object provides coupling // and propagator expressions. ParticleDataEntry* HResPtr; double mRes, GammaRes, m2Res, GamMRat, sigBW, widthOut; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for g g -> H0 (SM), H1, H2 or A3 (BSM). class Sigma1gg2H : public Sigma1Process { public: // Constructor. Sigma1gg2H(int higgsTypeIn) : higgsType(higgsTypeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for decay angles. 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 "gg";} virtual int resonanceA() const {return idRes;} private: // A H0, H1, H2 or A3 resonance object provides coupling // and propagator expressions. ParticleDataEntry* HResPtr; double mRes, GammaRes, m2Res, GamMRat, sigma; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for gamma gamma -> H0 (SM Higgs), H1, H2 or A3 (BSM Higgs). class Sigma1gmgm2H : public Sigma1Process { public: // Constructor. Sigma1gmgm2H(int higgsTypeIn) : higgsType(higgsTypeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for decay angles. 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 "gmgm";} virtual int resonanceA() const {return idRes;} private: // A H0, H1, H2 or A3 resonance object provides coupling // and propagator expressions. ParticleDataEntry* HResPtr; double mRes, GammaRes, m2Res, GamMRat, sigma; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for f fbar -> H Z0. // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma2ffbar2HZ : public Sigma2Process { public: // Constructor. Sigma2ffbar2HZ(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 idRes;} virtual int id4Mass() const {return 23;} virtual int resonanceA() const {return 23;} virtual int gmZmode() const {return 2;} private: // Store Z0 mass and width. double mZ, widZ, mZS, mwZS, thetaWRat, sigma0, openFracPair, coup2Z; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for f fbar -> H W+- (Standard Model Higgs). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma2ffbar2HW : public Sigma2Process { public: // Constructor. Sigma2ffbar2HW(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 idRes;} 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, thetaWRat, sigma0, openFracPairPos, openFracPairNeg, coup2W; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for f f' -> H f f' (Z0 Z0 fusion of SM or BSM Higgs). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma3ff2HfftZZ : public Sigma3Process { public: // Constructor. Sigma3ff2HfftZZ(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 idRes;} // Instructions for 3-body phase space with t-channel propagators. virtual int idTchan1() const {return 23;} virtual int idTchan2() const {return 23;} virtual double tChanFracPow1() const {return 0.05;} virtual double tChanFracPow2() const {return 0.9;} virtual bool useMirrorWeight() const {return true;} private: // Store standard factors. double mZS, prefac, sigma1, sigma2, openFrac, coup2Z; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for f_1 f_2 -> H f_3 f_4 (W+ W- fusion of SM or BSM Higgs). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma3ff2HfftWW : public Sigma3Process { public: // Constructor. Sigma3ff2HfftWW(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 idRes;} // Instructions for 3-body phase space with t-channel propagators. virtual int idTchan1() const {return 24;} virtual int idTchan2() const {return 24;} virtual double tChanFracPow1() const {return 0.05;} virtual double tChanFracPow2() const {return 0.9;} virtual bool useMirrorWeight() const {return true;} private: // Store standard prefactor. double mWS, prefac, sigma0, openFrac, coup2W; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for g g -> H Q Qbar (Q Qbar fusion of SM or BSM Higgs). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma3gg2HQQbar : public Sigma3Process { public: // Constructor. Sigma3gg2HQQbar(int idIn, int higgsTypeIn) : idNew(idIn), higgsType(higgsTypeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for decay angles. 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 "gg";} virtual int id3Mass() const {return idRes;} virtual int id4Mass() const {return idNew;} virtual int id5Mass() const {return idNew;} // Instructions for 3-body phase space with t-channel propagators. virtual int idTchan1() const {return idNew;} virtual int idTchan2() const {return idNew;} virtual double tChanFracPow1() const {return 0.4;} virtual double tChanFracPow2() const {return 0.2;} virtual bool useMirrorWeight() const {return false;} private: // Store flavour-specific process information and standard prefactor. double prefac, sigma, openFracTriplet, coup2Q; int idNew, higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for q qbar -> H Q Qbar (Q Qbar fusion of SM or BSM Higgs). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma3qqbar2HQQbar : public Sigma3Process { public: // Constructor. Sigma3qqbar2HQQbar(int idIn, int higgsTypeIn) : idNew(idIn), higgsType(higgsTypeIn) {} // Initialize process. virtual void initProc(); // Calculate flavour-independent parts of cross section. virtual void sigmaKin(); // Evaluate sigmaHat(sHat). virtual double sigmaHat() {return sigma;} // Select flavour, colour and anticolour. virtual void setIdColAcol(); // Evaluate weight for decay angles. 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 "qqbarSame";} virtual int id3Mass() const {return idRes;} virtual int id4Mass() const {return idNew;} virtual int id5Mass() const {return idNew;} // Instructions for 3-body phase space with t-channel propagators. virtual int idTchan1() const {return idNew;} virtual int idTchan2() const {return idNew;} virtual double tChanFracPow1() const {return 0.4;} virtual double tChanFracPow2() const {return 0.2;} virtual bool useMirrorWeight() const {return false;} private: // Store flavour-specific process information and standard prefactor. double prefac, sigma, openFracTriplet, coup2Q; int idNew, higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for q g -> H q (SM or BSM Higgs). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma2qg2Hq : public Sigma2Process { public: // Constructor. Sigma2qg2Hq(int idIn, int higgsTypeIn) : idNew(idIn), higgsType(higgsTypeIn) {} // 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 decay angles. 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 "qg";} virtual int id3Mass() const {return idRes;} virtual int id4Mass() const {return idNew;} private: // Store flavour-specific process information and standard prefactor. double m2W, thetaWRat, sigma, openFrac; int idNew, higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for g g -> H0 g (SM or BSM Higgs via heavy top loop). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma2gg2Hglt : public Sigma2Process { public: // Constructor. Sigma2gg2Hglt(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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(); // Evaluate weight for decay angles. 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 "gg";} virtual int id3Mass() const {return idRes;} private: // Store standard prefactor. double widHgg, sigma, openFrac; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for q g -> H q (SM or BSM Higgs via heavy top loop). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma2qg2Hqlt : public Sigma2Process { public: // Constructor. Sigma2qg2Hqlt(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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(); // Evaluate weight for decay angles. 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 "qg";} virtual int id3Mass() const {return idRes;} private: // Store standard prefactor. double widHgg, sigma, openFrac; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for q qbar -> H g (SM or BSM Higgs via heavy top loop). // (H can be H0 SM or H1, H2, A3 from BSM). class Sigma2qqbar2Hglt : public Sigma2Process { public: // Constructor. Sigma2qqbar2Hglt(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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(); // Evaluate weight for decay angles. 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 "qqbarSame";} virtual int id3Mass() const {return idRes;} private: // Store standard prefactor. double widHgg, sigma, openFrac; int higgsType, codeSave, idRes; string nameSave; }; //========================================================================== // A derived class for f fbar' -> H+-. class Sigma1ffbar2Hchg : public Sigma1Process { public: // Constructor. Sigma1ffbar2Hchg() {} // 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 decay angles. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar' -> H+-";} virtual int code() const {return 961;} virtual string inFlux() const {return "ffbarChg";} virtual int resonanceA() const {return 37;} private: // A H0 resonance object provides coupling and propagator expressions. ParticleDataEntry* HResPtr; double mRes, GammaRes, m2Res, GamMRat, m2W, thetaWRat, tan2Beta, sigBW, widthOutPos, widthOutNeg; }; //========================================================================== // A derived class for q g -> H+- q'. class Sigma2qg2Hchgq : public Sigma2Process { public: // Constructor. Sigma2qg2Hchgq(int idIn, int codeIn, string nameIn) : idNew(idIn), codeSave(codeIn), nameSave(nameIn) {} // 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 decay angles. 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 "qg";} virtual int id3Mass() const {return 37;} virtual int id4Mass() const {return idNew;} private: // Store flavour-specific process information and standard prefactor. int idNew, codeSave, idOld, idUp, idDn; string nameSave; double m2W, thetaWRat, tan2Beta, sigma, openFracPos, openFracNeg; }; //========================================================================== // A derived class for f fbar -> A0(H_3) h0(H_1) or A0(H_3) H0(H_2). class Sigma2ffbar2A3H12 : public Sigma2Process { public: // Constructor. Sigma2ffbar2A3H12(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 int id3Mass() const {return 36;} virtual int id4Mass() const {return higgs12;} private: // Store flavour-specific process information and standard prefactor. int higgsType, higgs12, codeSave; string nameSave; double coupZA3H12, m2Z, mGammaZ, thetaWRat, openFrac, sigma0; }; //========================================================================== // A derived class for f fbar -> H+- h0(H_1) or H+- H0(H_2). class Sigma2ffbar2HchgH12 : public Sigma2Process { public: // Constructor. Sigma2ffbar2HchgH12(int higgsTypeIn) : higgsType(higgsTypeIn) {} // 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 decay angles. 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 int id3Mass() const {return 37;} virtual int id4Mass() const {return higgs12;} private: // Store flavour-specific process information and standard prefactor. int higgsType, higgs12, codeSave; string nameSave; double coupWHchgH12, m2W, mGammaW, thetaWRat, openFracPos, openFracNeg, sigma0; }; //========================================================================== // A derived class for f fbar -> H+ H-. class Sigma2ffbar2HposHneg : public Sigma2Process { public: // Constructor. Sigma2ffbar2HposHneg() {} // 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 decay angles. virtual double weightDecay( Event& process, int iResBeg, int iResEnd); // Info on the subprocess. virtual string name() const {return "f fbar -> H+ H-";} virtual int code() const {return 1085;} virtual string inFlux() const {return "ffbarSame";} virtual int id3Mass() const {return 37;} virtual int id4Mass() const {return 37;} private: // Store flavour-specific process information and standard prefactor. double m2Z, mGammaZ, thetaWRat, eH, lH, openFrac, gamSig, intSig, resSig; }; //========================================================================== } // end namespace Pythia8 #endif // Pythia8_SigmaHiggs_H