main152
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// main152.cc is a part of the PYTHIA event generator.
// Copyright (C) 2024 Torbjorn Sjostrand.
// PYTHIA is licenced under the GNU GPL v2 or later, see COPYING for details.
// Please respect the MCnet Guidelines, see GUIDELINES for details.
// Authors:
// Torbjorn Sjostrand
// Keywords:
// Rescattering
// Low energy
// pT spectra
// Compare multiplicities and hadron spectra with and without rescattering,
// the former with or without rescattering between nearest string neighbours.
// Note: many other parameters could be used to vary the rescattering rate.
#include "Pythia8/Pythia.h"
using namespace Pythia8;
//--------------------------------------------------------------------------
int main() {
// Main settings. All particles with tau0 > maxTau0 fm are set stable.
int nEvent = 5000;
double maxTau0 = 100.;
// Histograms.
Hist multFin0("n_final, no rescattering", 100, 0., 800.);
Hist multRes0("n_resc, no rescattering ", 100, 0., 300.);
Hist pTpi0("pT pions no rescattering", 100, 0., 5.);
Hist pTk0("pT kaons no rescattering", 100, 0., 5.);
Hist pTp0("pT protons no rescattering", 100, 0., 5.);
Hist multFin1("n_final, no neighbours ", 100, 0., 800.);
Hist multRes1("n_resc, no neighbours ", 100, 0., 300.);
Hist pTpi1("pT pions, no neighbours ", 100, 0., 5.);
Hist pTk1("pT kaons, no neighbours ", 100, 0., 5.);
Hist pTp1("pT protons, no neighbours ", 100, 0., 5.);
Hist multFin2("n_final, all rescatter", 100, 0., 800.);
Hist multRes2("n_resc, all rescatter ", 100, 0., 300.);
Hist pTpi2("pT pions, all rescatter ", 100, 0., 5.);
Hist pTk2("pT kaons, all rescatter ", 100, 0., 5.);
Hist pTp2("pT protons, all rescatter ", 100, 0., 5.);
// Loop over the three possible scenarios being compared.
for (int ic = 0; ic < 3; ++ic) {
// Create Pythia instance. Shorthand for event.
Pythia pythia;
Event& event = pythia.event;
// Process selection: nondiffractive pp.
pythia.readString("SoftQCD:nonDiffractive = on");
pythia.readString("Beams:eCM = 13000.");
// Turn rescattering on, which also requires vertices on.
if (ic > 0) {
pythia.readString("HadronLevel:Rescatter = on");
pythia.readString("Fragmentation:setVertices = on");
pythia.readString("PartonVertex:setVertex = on");
// Rescattering details.
//pythia.readString("Rescattering:quickCheck = off");
if (ic == 1) pythia.readString("Rescattering:nearestNeighbours = off");
}
// Switch off all decays with lifetime > maxTau0.
pythia.readString("ParticleDecays:limitTau0 = on");
pythia.settings.parm("ParticleDecays:tau0Max", maxTau0 * FM2MM);
// Initialize Pythia.
if (!pythia.init()) {
cout << " Pythia failed to initialize." << endl;
return -1;
}
// References to relevant histograms.
Hist& multFin = (ic == 0) ? multFin0 : ((ic == 1) ? multFin1 : multFin2);
Hist& multRes = (ic == 0) ? multRes0 : ((ic == 1) ? multRes1 : multRes2);
Hist& pTpi = (ic == 0) ? pTpi0 : ((ic == 1) ? pTpi1 : pTpi2);
Hist& pTk = (ic == 0) ? pTk0 : ((ic == 1) ? pTk1 : pTk2);
Hist& pTp = (ic == 0) ? pTp0 : ((ic == 1) ? pTp1 : pTp2);
// Generate events.
int nSuccess = 0;
for (int iEvent = 0; iEvent < nEvent; ++iEvent) {
if (!pythia.next()) continue;
++nSuccess;
// Final multiplicity and number of rescatterings.
int nFin = event.nFinal(false);
int nRes = 0;
for (Particle& particle : event) {
if (particle.isHadron() && !particle.isFinal()) {
Particle& daughter = event[particle.daughter1()];
if (daughter.isHadron() && daughter.statusAbs()/10 == 15) nRes += 1;
}
}
// Exactly two hadrons participate in each rescattering. Fill histograms.
nRes /= 2;
multFin.fill(nFin + 0.5);
multRes.fill(nRes + 0.5);
// Hadron pT spectra at central rapidities.
for (Particle& particle : event) {
if (particle.isHadron() && particle.isFinal()
&& abs(particle.y()) < 2.) {
int idAbs = particle.idAbs();
double pT = particle.pT();
if (idAbs == 211 || idAbs == 111) pTpi.fill(pT);
else if (idAbs == 311 || idAbs == 321 || idAbs == 310
|| idAbs == 130) pTk.fill(pT);
else if (idAbs == 2212) pTp.fill(pT);
}
}
// End of event loop. Normalize and print histograms.
}
pythia.stat();
multFin *= 1. / (8. * nSuccess);
multRes *= 1. / (3. * nSuccess);
pTpi *= 20. / nSuccess;
pTk *= 20. / nSuccess;
pTp *= 20. / nSuccess;
cout << multFin << multRes << pTpi << pTk << pTp;
// End loop over three cases.
}
// Plot histograms.
HistPlot hpl("main152plot");
hpl.frame("out152plot", "Hadronic multiplicity", "n", "dN/dn");
hpl.add( multFin0, "", "no rescattering");
hpl.add( multFin1, "", "partial rescattering");
hpl.add( multFin2, "", "full rescattering");
hpl.plot(true);
hpl.frame("", "Number of rescatterings", "n", "dN/dn");
//hpl.add( multRes0, "", "no rescattering");
hpl.add( multRes1, ",g", "partial rescattering");
hpl.add( multRes2, ",r", "full rescattering");
hpl.plot(true);
hpl.frame("", "Pion pT distribution for |y| < 2", "pT (GeV)", "dN/dpT");
hpl.add( pTpi0, "", "no rescattering");
hpl.add( pTpi1, "", "partial rescattering");
hpl.add( pTpi2, "", "full rescattering");
hpl.plot(true);
hpl.frame("", "Kaon pT distribution for |y| < 2", "pT (GeV)", "dN/dpT");
hpl.add( pTk0, "", "no rescattering");
hpl.add( pTk1, "", "partial rescattering");
hpl.add( pTk2, "", "full rescattering");
hpl.plot(true);
hpl.frame("", "Proton pT distribution for |y| < 2", "pT (GeV)", "dN/dpT");
hpl.add( pTp0, "", "no rescattering");
hpl.add( pTp1, "", "partial rescattering");
hpl.add( pTp2, "", "full rescattering");
hpl.plot(true);
// Done.
return 0;
}