The π+π- Coulomb interaction study and its use in the data processing

Abstract

In this work the Coulomb effects (Coulomb correlations) in π+π- pairs produced in p + Ni collisions at 24 GeV/c, are studied using experimental π+π- pair distributions in Q, the relative momentum in the pair center of mass system (c.m.s), and its projections QL (longitudinal component) and Qt (transverse component) relative to the pair direction in the laboratory system (l.s.). The Q, QL, and Qt distributions of the Coulomb pairs in the c.m.s. have been simulated assuming they are described by the phase space modified by the known point-like Coulomb correlation function AC(Q), corrected for small effects due to the nonpoint-like pair production and the strong two-pion interaction. The same distributions of non-Coulomb pairs have been simulated according to the phase space, but without AC(Q). It is shown that the number of Coulomb pairs in all Qt intervals, including the small Qt (small opening angles θ in the l.s.) is calculated with the theoretical precision better than 2\%. The comparison of the simulated and experimental numbers of Coulomb pairs at small Qt allows us to check and correct the detection efficiency for the pairs with small θ (0.06 mrad and smaller). It is shown that Coulomb pairs can be used as a new physical tool to check and correct the quality of the simulated events. The special property of the Coulomb pairs is the possibility of checking and correcting the detection efficiency, especially for the pairs with small opening angles.