Feasibility study to characterize the production of antineutrons in high energy pp collisions through charge exchange interactions

Abstract

Simulations to evaluate the feasibility of n identification and kinematic characterization via the hadronic charge exchange (CEX) interaction n+n→ p+p are reported. The target neutrons are those composing the silicon nuclei of which inner tracking devices present in LHC experiments are made. Simulations of pp collisions in PYTHIA were carried out at different energies to investigate n production and the expected n energy spectra. Then, two types of GEANT4 simulations were performed, placing an n point source at the ALICE primary vertex as a working example. In the first simulation, the Ek was kept at an arbitrary (1 GeV) fix value to develop an n identification and kinematics reconstruction protocol. The second GEANT4 simulation used the resulting PYTHIA at spp=13 TeV n energy spectra. In both simulations, the occurrence of CEX interactions was identified by the unique outgoing p. The simplified simulation allowed to estimate a 0.11% CEX-interaction identification efficiency at Ek = 1 GeV. The p CEX-partner identification is challenging because of the presence of silicon nucleus-fragmentation protons. Momentum correlations between the n and all possible pp pairs showed that p CEX-partner identification and n kinematics reconstruction corresponds to minimal momentum-loss events. The use of ITS dE/dx information is found to improve n identification and kinematic characterization in both simulations. The final protocol applied to the realistic simulation resulted in a n identification and kinematic reconstruction efficiency of 0.006%, based solely on pp pair observable. Thus, the expected rate of identified and kinematically reconstructed n should lie in the order of 100,000 per second, illustrating the feasibility of the method.