Line shape analysis of (1405) in γ p → K+-π+ reaction using convolutional neural network

Abstract

Interpreting peaks or dips that appear in an invariant mass distribution is a recurring challenge in hadron physics. These enhancements can be ambiguous, especially near a two-hadron threshold since kinematical and dynamical effects play an important role in their nature. One such enhancement is an exotic baryon (1405) which was first observed in 1973. Despite the few available experimental data, the statistics of the measurements of (1405) have improved for line shape analysis. The present consensus is that it is a structure of two poles both on the second Riemann sheet. However, there are still investigations of other pole structures corresponding to (1405). Lately, the use of a deep neural network in analyzing these line shapes has been proven to be effective, especially in distinguishing pole structures. Thus, in this study, we develop a convolutional neural network, a type of DNN, to determine the general pole structure that corresponds to (1405) found in the -π+ invariant mass distribution measured by CLAS in their experiment involving the γ p → K+π reaction. The CNN is trained using a two-channel uniformized S-matrix allowing us to control the position and the corresponding Riemann sheet of the poles. Our preliminary results show that the trained CNN can accurately distinguish pole structures in the -π+ invariant mass distribution and agrees with the present consensus of a two-pole structure. This supports the preceding works on the (1405) and requires a thorough analysis of +π- and 0π0 invariant mass spectra.