English

Two-dimensional total absorption spectroscopy with conditional generative adversarial networks

Nuclear Experiment 2023-12-15 v3 Artificial Intelligence

Abstract

We explore the use of machine learning techniques to remove the response of large volume γ\gamma-ray detectors from experimental spectra. Segmented γ\gamma-ray total absorption spectrometers (TAS) allow for the simultaneous measurement of individual γ\gamma-ray energy (Eγ_\gamma) and total excitation energy (Ex_x). Analysis of TAS detector data is complicated by the fact that the Ex_x and Eγ_\gamma quantities are correlated, and therefore, techniques that simply unfold using Ex_x and Eγ_\gamma response functions independently are not as accurate. In this work, we investigate the use of conditional generative adversarial networks (cGANs) to simultaneously unfold ExE_{x} and EγE_{\gamma} data in TAS detectors. Specifically, we employ a \texttt{Pix2Pix} cGAN, a generative modeling technique based on recent advances in deep learning, to treat \rawmatrix~ matrix unfolding as an image-to-image translation problem. We present results for simulated and experimental matrices of single-γ\gamma and double-γ\gamma decay cascades. Our model demonstrates characterization capabilities within detector resolution limits for upwards of 93% of simulated test cases.

Keywords

Cite

@article{arxiv.2206.11792,
  title  = {Two-dimensional total absorption spectroscopy with conditional generative adversarial networks},
  author = {Cade Dembski and Michelle P. Kuchera and Sean Liddick and Raghu Ramanujan and Artemis Spyrou},
  journal= {arXiv preprint arXiv:2206.11792},
  year   = {2023}
}
R2 v1 2026-06-24T12:02:01.964Z