Rivet analyses

Mass and angular distributions in J/ψ → γKS0KS0η decays

Experiment: BESIII (BEPC)

Inspire ID: 1376282

Status: VALIDATED NOHEPDATA

Authors: - Peter Richardson

References: - Phys.Rev.Lett. 115 (2015) 9, 091803

Beams: e- e+

Beam energies: (1.6, 1.6)GeV

Run details: - e+e- > J/psi

Measurement of mass and angular distributions in J/ψ → γKS0KS0η decays.

Source code:BESIII_2015_I1376282.cc

// -*- C++ -*-
#include "Rivet/Analysis.hh"
#include "Rivet/Projections/Beam.hh"
#include "Rivet/Projections/UnstableParticles.hh"
#include "Rivet/Projections/DecayedParticles.hh"

namespace Rivet {


  /// @brief J/psi -> gamma eta KS0,KS0
  class BESIII_2015_I1376282 : public Analysis {
  public:

    /// Constructor
    RIVET_DEFAULT_ANALYSIS_CTOR(BESIII_2015_I1376282);


    /// @name Analysis methods
    /// @{

    /// Book histograms and initialise projections before the run
    void init() {
      // Initialise and register projections
      UnstableParticles ufs = UnstableParticles(Cuts::abspid==443);
      declare(ufs, "UFS");
      DecayedParticles PSI(ufs);
      PSI.addStable(PID::K0S);
      PSI.addStable(PID::ETA);
      declare(PSI, "PSI");
      declare(Beam(), "Beams");
      // Book histograms
      for(unsigned int ix=0;ix<6;++ix)
    book(_h[ix],1,1,1+ix);
    }

    // angle cuts due regions of BES calorimeter
    bool vetoPhoton(const double & cTheta) {
      return cTheta>0.92 || (cTheta>0.8 && cTheta<0.86);
    }

    /// Perform the per-event analysis
    void analyze(const Event& event) {
      // get the axis, direction of incoming electron
      const ParticlePair& beams = apply<Beam>(event, "Beams").beams();
      Vector3 axis;
      if(beams.first.pid()>0)
    axis = beams.first .momentum().p3().unit();
      else
    axis = beams.second.momentum().p3().unit();
      // find the J/psi decays
      static const map<PdgId,unsigned int> & mode = { { 221,1}, { 310,2},{ 22,1}};
      DecayedParticles PSI = apply<DecayedParticles>(event, "PSI");
      if( PSI.decaying().size()!=1) vetoEvent;
      if(!PSI.modeMatches(0,4,mode)) vetoEvent;
      const Particle  & eta = PSI.decayProducts()[0].at(221)[0];
      const Particles & K0  = PSI.decayProducts()[0].at(310);
      const Particle  & gam = PSI.decayProducts()[0].at( 22)[0];
      _h[0]->fill((K0[0].momentum()+K0[1].momentum()+eta.momentum()).mass());
      _h[1]->fill((K0[0].momentum()+K0[1].momentum()).mass());
      for(unsigned int ix=0;ix<2;++ix)
    _h[2]->fill((K0[ix].momentum()+eta.momentum()).mass());
      double cTheta = axis.dot(gam.p3().unit());
      // photon angle
      if(vetoPhoton(abs(cTheta))) vetoEvent;
      _h[3]->fill(cTheta);
      // remaining angles
      LorentzTransform boost1 = LorentzTransform::mkFrameTransformFromBeta(PSI.decaying()[0].momentum().betaVec());
      FourMomentum pGamma    = boost1.transform(gam.momentum());
      FourMomentum pHadron = boost1.transform(K0[0].momentum()+K0[1].momentum()+eta.momentum());
      LorentzTransform boost2 = LorentzTransform::mkFrameTransformFromBeta(pHadron.betaVec());
      Vector3 axis1 = pGamma.p3().unit();
      Vector3 axis2 = boost2.transform(boost1.transform(eta.momentum())).p3().unit();
      _h[4]->fill(axis1.dot(axis2));
      FourMomentum pKK = boost2.transform(boost1.transform(K0[0].momentum()+K0[1].momentum()));
      axis2 = pKK.p3().unit();
      LorentzTransform boost3 = LorentzTransform::mkFrameTransformFromBeta(pKK.betaVec());
      for(unsigned ix=0;ix<2;++ix) {
    Vector3 axis3 = boost3.transform(boost2.transform(boost1.transform(K0[ix].momentum()))).p3().unit();
    _h[5]->fill(axis3.dot(axis2));
      }
    }


    /// Normalise histograms etc., after the run
    void finalize() {
      for(unsigned int ix=0;ix<6;++ix)
    normalize(_h[ix],1.,false);
    }

    /// @}

    /// @name Histograms
    /// @{
    Histo1DPtr _h[6];
    /// @}


  };


  RIVET_DECLARE_PLUGIN(BESIII_2015_I1376282);

}