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Explainable deep-learning detection of microplastic fibers via polarization-resolved holographic microscopy

arXiv (Cornell University) 2026 Score: 40 ? 0–100 AI score estimating relevance to the microplastics field. Papers below 30 are filtered from public browse.

Jaromír Běhal, Marika Valentino, Marika Valentino, Giulia Dalla Fontana, Raffaella Mossotti Marika Valentino, Raffaella Mossotti Jan Appel, Jan Appel, Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Jan Appel, Marika Valentino, Giulia Dalla Fontana, Marika Valentino, Raffaella Mossotti Raffaella Mossotti Jan Appel, Giulia Dalla Fontana, Giulia Dalla Fontana, Giulia Dalla Fontana, Jaromír Běhal, Jaromír Běhal, Jaromír Běhal, Raffaella Mossotti Marika Valentino, Marika Valentino, Marika Valentino, Marika Valentino, Marika Valentino, Marika Valentino, Raffaella Mossotti Marika Valentino, Giulia Dalla Fontana, Giulia Dalla Fontana, Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Lisa Miccio, Lisa Miccio, Giulia Dalla Fontana, Jaromír Běhal, Jaromír Běhal, Jaromír Běhal, Giulia Dalla Fontana, Lisa Miccio, Lisa Miccio, Vittorio Bianco, Vittorio Bianco, Giulia Dalla Fontana, Vittorio Bianco, Giulia Dalla Fontana, Vittorio Bianco, Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Jaromír Běhal, Giulia Dalla Fontana, Giulia Dalla Fontana, Giulia Dalla Fontana, Giulia Dalla Fontana, Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Raffaella Mossotti Giulia Dalla Fontana, Miroslav Ježek, Raffaella Mossotti Miroslav Ježek, Giulia Dalla Fontana, Miroslav Ježek, Miroslav Ježek, Giulia Dalla Fontana, Pietro Ferraro, Pietro Ferraro, Pietro Ferraro, Pietro Ferraro, Jaromír Běhal, Jaromír Běhal, Raffaella Mossotti

Summary

This study used polarized light microscopy combined with a deep-learning AI to automatically distinguish microplastic fibers from natural fibers like cotton and wool, achieving 96.7% accuracy. Misidentifying natural particles as microplastics (or vice versa) is a persistent problem in environmental monitoring, and this explainable AI approach reveals exactly which optical properties drive the classification. More accurate fiber identification will improve the reliability of microplastic contamination data in food, water, and environmental samples.

Polymers

PA PE PET PP

Body Systems

Nervous

Reliable identification of microplastic fibers is crucial for environmental monitoring but remains analytically challenging. We report an explainable deep-learning framework for classifying microplastic and natural microfibers using polarization-resolved digital holographic microscopy. From multiplexed holograms, the complex Jones matrix of each fiber was reconstructed to extract polarization eigen-parameters describing optical anisotropy. Statistical descriptors of nine polarization characteristics formed a 72-dimensional feature vector for a total of 296 fibers spanning six material classes, including polyamide 6, polyethylene terephthalate, polyamide 6.6, polypropylene, cotton and wool. The designed fully connected deep neural network achieved an accuracy of 96.7 % on the validation data, surpassing that of common machine-learning classifiers. Explainable artificial intelligence analysis with Shapley additive explanations identified eigenvalue-ratio quantities as dominant predictors, revealing the physical basis for classification. An additional reduced-feature model with the preserved architecture exploiting only these most significant eigenvalue-based characteristics retained high accuracy (93.3 %), thereby confirming their dominant role while still outperforming common machine-learning classifiers. These results establish polarization-based features as distinctive optical fingerprints and demonstrate the first explainable deep-learning approach for automated microplastic fiber identification.

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