A novel machine learning method to detect double-$\Lambda$ hypernuclear events in nuclear emulsions
Abstract
A novel method was developed to detect double- hypernuclear events in nuclear emulsions using machine learning techniques. The object detection model, the Mask R-CNN, was trained using images generated by Monte Carlo simulations, image processing, and image-style transformation based on generative adversarial networks. Despite being exclusively trained on events, the model achieved a detection efficiency of 93.8 for and 82.0 for events in the produced images. In addition, the model demonstrated its ability to detect the event named the Nagara event, which is the only uniquely identified double- hypernuclear event reported to date. It also exhibited a proper segmentation of the event topology. Furthermore, after analyzing 0.2 of the entire emulsion data from the J-PARC E07 experiment utilizing the developed approach, six new candidates for double- hypernuclear events were detected, suggesting that more than 2000 double-strangeness hypernuclear events were recorded in the entire dataset. This method is sufficiently effective for mining more latent double- hypernuclear events recorded in nuclear emulsion sheets by reducing the time required for manual visual inspection by a factor of five hundred.
Cite
@article{arxiv.2409.01657,
title = {A novel machine learning method to detect double-$\Lambda$ hypernuclear events in nuclear emulsions},
author = {Yan He and Vasyl Drozd and Hiroyuki Ekawa and Samuel Escrig and Yiming Gao and Ayumi Kasagi and Enqiang Liu and Abdul Muneem and Manami Nakagawa and Kazuma Nakazawa and Christophe Rappold and Nami Saito and Takehiko R. Saito and Shohei Sugimoto and Masato Taki and Yoshiki K. Tanaka and He Wang and Ayari Yanai and Junya Yoshida and Hongfei Zhang},
journal= {arXiv preprint arXiv:2409.01657},
year = {2024}
}