A Deep Learning Framework for Disentangling Triangle Singularity and Pole-Based Enhancements
Abstract
Enhancements in the invariant mass distribution or scattering cross-section are usually associated with resonances. However, the nature of exotic signals found near hadron-hadron thresholds remain a puzzle today due to the presence of experimental uncertainties. In fact, a purely kinematical triangle diagram is also capable of producing similar structures, but do not correspond to any unstable quantum state. In this paper, we report for the first time, that a deep neural network can be trained to distinguish triangle singularity from pole-based enhancements with a reasonably high accuracy of discrimination between the two seemingly identical line shapes. We also identify the type of triangle enhancement that can be misidentified as a dynamic pole structure. We apply our method to confirm that the state is not due to a triangle singularity, but is more consistent with a pole-based interpretation, as determined solely through pure line-shape analysis. Lastly, we explain how our method can be used as a model-selection framework useful in studying other exotic hadron candidates.
Cite
@article{arxiv.2403.18265,
title = {A Deep Learning Framework for Disentangling Triangle Singularity and Pole-Based Enhancements},
author = {Darwin Alexander O. Co and Vince Angelo A. Chavez and Denny Lane B. Sombillo},
journal= {arXiv preprint arXiv:2403.18265},
year = {2024}
}
Comments
17 pages, 11 figures; accepted in Physical Review D