On the background in the $\gamma p \to \omega(\pi^0\gamma) p$ reaction and mixed event simulation

TL;DR

This paper evaluates background sources in the $ ightarrow$ reaction, compares simulation methods with experimental data, and finds that photon misidentification significantly affects background at low invariant masses.

Contribution

It introduces a mixed event simulation approach to accurately reproduce background events in $ ightarrow$ reactions, highlighting the role of photon misidentification.

Findings

Background from $ o o$ accounts for data above 700 MeV

Photon misidentification explains missing strength at lower masses

Event mixing simulation reproduces low-mass background well

Abstract

In this paper we evaluate sources of background for the $\gamma p \to \omega p$, with the $\omega$ detected through its $\pi^0 \gamma$ decay channel, to compare with the experiment carried out at ELSA. We find background from $\gamma p \to \pi^0 \pi^0 p$ followed by decay of a $\pi^0$ into two $\gamma$, recombining one $\pi^0$ and one $\gamma$, and from the $\gamma p \to \pi^0 \eta p$ reaction with subsequent decay of the $\eta$ into two photons. This background accounts for the data at $\pi^0 \gamma$ invariant masses beyond 700 MeV, but strength is missing at lower invariant masses which was attributed to photon misidentification events, which we simulate to get a good reproduction of the experimental background. Once this is done, we perform an event mixing simulation to reproduce the calculated background and we find that the method provides a good description of the background at low $\pi^0 \gamma$ invariant masses but fakes the background at high invariant masses, making background events at low invariant masses, which are due to $\gamma$ misidentification events, responsible for the background at high invariant masses which is due to the $\gamma p \to \pi^0 \pi^0 p$ and $\gamma p \to \pi^0 \eta p$ reactions.