Fluorescent Nuclear Track Detectors (FNTDs) provide high spatial resolution, wide linear energy transfer coverage, and reusability, making them well-suited for high-energy neutron dosimetry. When neutrons traverse a polyethylene converter, recoil protons are generated, and their tracks are stored inside the FNTDs and visualised through optical readout. Traditional analysis of FNTD images relies on deterministic algorithms or machine learning methods with explicit feature definition, limiting their general extension. In contrast, deep learning networks can extract image features enabling generalisation across different neutron energy spectra and dose values. In this study, a deep learning network was trained on images of FNTDs irradiated at six mono-energetic neutron energies and tested on images of FNTDs exposed to a broad-spectrum 241 Am-Be neutron source. Using raw images of irradiated FNTDs as input, the network predicted the proton tracks which were later counted. For the 241 Am-Be test dataset, a dose–response curve of identified tracks over ambient dose equivalent was fitted, and the sensitivity in terms of H ∗ ( 10 ) was extracted from the slope. When the fit was applied on the whole H ∗ ( 10 ) range, from 0 mSv up to 100 mSv, the predicted sensitivity for 241 Am-Be was S p r e d = ( 2280 ± 20 ) tracks mSv − 1 cm − 2 . The relative deviation of this predicted sensitivity from the reference sensitivity was 5.8%. When the fit considered only the H ∗ ( 10 ) range of the training dataset, namely from 5 mSv to 15 mSv, the predicted sensitivity for 241 Am-Be was S p r e d = ( 2500 ± 60 ) tracks mSv − 1 cm − 2 . This led to a relative deviation from the reference sensitivity of only 1.2%. Despite being trained solely on mono-energetic data, the model successfully generalised to the 241 Am-Be energy spectrum. • Fluorescent Nuclear Track Detector (FNTD) images segmented with deep learning. • The self-configuring nnU-Net framework was used for FNTDs. • FNTDs irradiated with mono-energetic neutrons were used as the training dataset. • Successful track identification of recoil protons. • FNTDs irradiated with broad spectrum 241 Am-Be properly predicted.
Thai et al. (Sun,) studied this question.