Rivet analyses
Measurement of very forward neutron energy spectra for 7 TeV proton-proton collisions at the Large Hadron Collider
Experiment: LHCF (LHC)
Inspire ID: 1351909
Status: VALIDATED
Authors: - Eugenio Berti - LHCf collaboration
References: - Phys. Lett. B 750 (2015) 360-366
Beams: p+ p+
Beam energies: (3500.0, 3500.0)GeV
Run details: - Differential production cross section of neutrons in p-p collisions in the very forward region expressed as a function of energy. Note that, being LHCf detector locate 140m away from IP, two additional effects must be taken into account. They are particles decay in the transport though the beam pipe and trajectories bending due to the dipole magnet. Because of them, the final energy spectra included about 0 − 6 % of other hadrons, mainly Λ0 and K0. These effects are considered in the Rivet code making use of some approximations that are able to reproduce the model distributions shown in the paper within 15% in most cases, depending on the model, the pseudorapidity region and the energy bin.
The Large Hadron Collider forward (LHCf) experiment is designed to use the LHC to verify the hadronic-interaction models used in cosmic-ray physics. Forward baryon production is one of the crucial points to understand the development of cosmic-ray showers. We report the neutron-energy spectra for LHC $\sqrt{s}$ = 7 TeV proton–proton collisions with the pseudo-rapidity η ranging from 8.81 to 8.99, from 8.99 to 9.22, and from 10.76 to infinity. The measured energy spectra obtained from the two independent calorimeters of Arm1 and Arm2 show the same characteristic feature before unfolding the difference in the detector responses. We unfolded the measured spectra by using the multidimensional unfolding method based on Bayesian theory, and the unfolded spectra were compared with current hadronic-interaction models. The QGSJET II-03 model predicts a high neutron production rate at the highest pseudo-rapidity range similar to our results and the DPMJET 3.04 model describes our results well at the lower pseudo-rapidity ranges. However no model perfectly explains the experimental results in the whole pseudo-rapidity range. The experimental data indicate the most abundant neutron production rate relative to the photon production, which does not agree with predictions of the models.
Source
code:LHCF_2015_I1351909.cc
// -*- C++ -*-
#include "Rivet/Analysis.hh"
#include "Rivet/Projections/FinalState.hh"
#include "Rivet/Projections/Beam.hh"
namespace Rivet {
/// @brief Add a short analysis description here
class LHCF_2015_I1351909 : public Analysis {
public:
/// Constructor
RIVET_DEFAULT_ANALYSIS_CTOR(LHCF_2015_I1351909);
static constexpr bool lhcf_like = true;
static constexpr int ndecay = 1;
static constexpr int nbeam = 2;
static constexpr double D1_begin = 82000.; //mm 60000.; //mm
static constexpr double D1_end = 82000; //mm 90000.; //mm
static constexpr double IPtoLHCf = 141050.; //mm
/// @name Analysis methods
bool isParticleFromCollision(const Particles& parents, const Beam& beams) const {
bool beam[nbeam]={false};
if (parents.size()==nbeam) {
for ( int ipar=0; ipar < nbeam; ++ipar ) {
if ( parents[ipar].genParticle() == beams.beams().first.genParticle() ||
parents[ipar].genParticle() == beams.beams().second.genParticle() )
beam[ipar] = true;
}
if(beam[0] && beam[1]) return true;
}
return false;
}
bool isDeviated(Particle p, Particle parent) { //Select/Remove particles decayed between IP and LHCf
ConstGenVertexPtr pv = p.genParticle()->production_vertex();
assert(pv != nullptr);
const double decay_vertex = pv->position().z()/mm;
const double parent_charge = PID::charge(parent.pid());
const double descendant_charge = PID::charge(p.pid());
if(parent_charge == 0) { //Particles produced by neutral parent decay
if(descendant_charge == 0) {
return false;
} else {
if(decay_vertex >= D1_end)
return false;
else
return true; //Remove charged descendants produced from decay before end of D1
}
} else { //Particles produced by charged parent decay
if(decay_vertex <= D1_begin) {
if(descendant_charge == 0)
return false;
else
return true; //Remove charged descendants produced from decay before end of D1
} else {
return true; //Remove particles produced by charged parent decay after begin of D1
}
}
return false;
}
bool isSameParticle(Particle p1, Particle p2) {
if(p1.pid() == p2.pid() &&
mom(p1).t() == mom(p2).t() &&
mom(p1).x() == mom(p2).x() &&
mom(p1).y() == mom(p2).y() &&
mom(p1).z() == mom(p2).z())
return true;
else
return false;
}
bool isAlreadyProcessed(Particle p, vector<Particle> list) {
for(unsigned int ipar=0; ipar<list.size(); ++ipar)
if(isSameParticle(p, list[ipar]))
return true;
return false;
}
/// This method return a fake pseudorapidity to check id decayed particle is in LHCf acceptance
double RecomputeEta(Particle p) {
ConstGenVertexPtr pv = p.genParticle()->production_vertex();
const double x0 = pv->position().x()/mm;
const double y0 = pv->position().y()/mm;
const double z0 = pv->position().z()/mm;
const double px = p.px()/MeV;
const double py = p.py()/MeV;
const double pz = abs(p.pz()/MeV);
const double dist_to_lhcf = IPtoLHCf - z0;
const double x1 = x0 + (dist_to_lhcf * px/pz);
const double y1 = y0 + (dist_to_lhcf * py/pz);
const double r = sqrt(pow(x1, 2.)+pow(y1, 2.));
const double theta = atan(abs(r / IPtoLHCf));
const double pseudorapidity = - log (tan (theta/2.) );
return pseudorapidity;
}
/// Book histograms and initialise projections before the run
void init() {
// Initialise and register projections
// declare(FinalState("FS");
declare(FinalState(), "FS");
declare(Beam(), "Beams");
// Book histograms
book(_h_n_en_eta1, 1, 1, 1);
book(_h_n_en_eta2, 1, 1, 2);
book(_h_n_en_eta3, 1, 1, 3);
}
/// Perform the per-event analysis
void analyze(const Event& event) {
const FinalState &fs = apply<FinalState> (event, "FS");
Particles fs_particles = fs.particles();
const Beam & beams = apply<Beam> (event, "Beams");
vector<Particle> processed_parents;
processed_parents.clear();
for (Particle& p: fs_particles ) {
if(p.pz()/GeV<0.) continue;
double eta = 0.;
double en = 0.;
if(lhcf_like) {
//======================================================================
//========== LHCf-like analysis ========================================
//======================================================================
vector<Particle> parents = p.parents();
if(isParticleFromCollision(parents, beams)) { //Particles directly produced in collisions
if(!PID::isHadron(p.pid())) continue; //Remove non-hadron particles
if(PID::charge(p.pid()) != 0) continue; //Remove charged particles
eta = p.eta();
en = p.E()/GeV;
} else if(parents.size() == ndecay) { //Particles produced from decay
ConstGenVertexPtr pv = p.genParticle()->production_vertex();
assert(pv != nullptr);
const double decay_vertex = pv->position().z()/mm;
Particle parent = parents[0];
if(decay_vertex < IPtoLHCf) { //If decay happens before LHCf we consider descendants
if(!PID::isHadron(p.pid())) continue; //Remove non-hadron descendants
if(isDeviated(p, parent)) continue; //Remove descendants deviated by D1
eta = RecomputeEta(p);
en = p.E()/GeV;
} else {//If decay happens after LHCf we consider parents
vector<Particle> ancestors;
ancestors.clear();
int ngeneration=0;
bool isValid=true;
bool isEnded=false;
while(!isEnded) //Loop over all generations in the decay
{
vector<Particle> temp_part;
temp_part.clear();
if(ngeneration==0) {
parent = parents[0];
temp_part = parent.parents();
}
else {
parent = ancestors[0];
temp_part = parent.parents();
}
ancestors.clear();
ancestors = temp_part;
Particle ancestor = ancestors[0];
if(isParticleFromCollision(ancestors, beams)) { //if we found first particles produced in collisions we consider them
isEnded=true;
if(!PID::isHadron(parent.pid())) isValid=false; //Remove non-hadron ancestors/parents
if(PID::charge(parent.pid()) != 0) isValid=false; //Remove charged ancestors/parents
if(isAlreadyProcessed(parent, processed_parents))
isValid=false; //Remove already processed ancestors/parents when looping other descendants
else
processed_parents.push_back(parent); //Fill ancestors/parents in the list
eta = parent.eta();
en = parent.E()/GeV;
} else if (ancestors.size() == ndecay) { //if we found first particles produced entering LHCf we consider them
ConstGenVertexPtr pv_prev = parent.genParticle()->production_vertex();
assert(pv_prev != NULL);
const double previous_decay_vertex = pv_prev->position().z()/mm;
if(previous_decay_vertex < IPtoLHCf) {
isEnded=true;
if(!PID::isHadron(parent.pid())) isValid=false; //Remove non-hadron ancestors/parents
if(isDeviated(parent, ancestor)) isValid=false; //Remove ancestors/parents deviated by D1
if(isAlreadyProcessed(parent, processed_parents))
isValid=false; //Remove already processed ancestors/parents when looping other descendants
else
processed_parents.push_back(parent); //Fill ancestors/parents in the list
eta = RecomputeEta(parent);
en = parent.E()/GeV;
}
} else { //This condition should never happen
cout << "Looping over particles generation ended without match : Exit..." << endl;
vetoEvent;
}
++ngeneration;
}
if(!isValid) continue;
}
} else { //This condition should never happen
cout << "Particle seems not to be produced in collision or decay : Exit..." << endl;
vetoEvent;
}
} else {
//======================================================================
//========== Only neutrons at IP =======================================
//======================================================================
vector<Particle> parents = p.parents();
if(p.pid() != 2112 ) continue;
eta = p.eta();
en = p.E()/GeV;
//}
}
// Fill histograms
if( eta > 10.76 ){
_h_n_en_eta1->fill( en );
}else if(eta > 8.99 && eta < 9.22){
_h_n_en_eta2->fill( en );
}else if(eta > 8.81 && eta < 8.99){
_h_n_en_eta3->fill( en );
}
}
}
/// Normalise histograms etc., after the run
void finalize() {
scale(_h_n_en_eta1, crossSection()/millibarn/sumOfWeights()); // norm to cross section
scale(_h_n_en_eta2, crossSection()/millibarn/sumOfWeights()); // norm to cross section
scale(_h_n_en_eta3, crossSection()/millibarn/sumOfWeights()); // norm to cross section
}
// @}
private:
/// @name Histograms
// @{
Histo1DPtr _h_n_en_eta1;
Histo1DPtr _h_n_en_eta2;
Histo1DPtr _h_n_en_eta3;
// @}
};
RIVET_DECLARE_PLUGIN(LHCF_2015_I1351909);
}