Justification of a High-Energy Regime for Water Disinfection by an Electron Beam

doi:10.26565/2312-4334-2025-3-46

Stepan H. Karpus Lutsk National Technical University, Lutsk, Ukraine; National Scientific Centre ”Kharkiv Institute of Physics and Technology”, Kharkiv, Ukraine https://orcid.org/0000-0002-1087-9245
Oleh O. Shopen National Scientific Centre ”Kharkiv Institute of Physics and Technology”, Kharkiv, Ukraine https://orcid.org/0000-0003-3158-8081
Dmytro A. Zakharchuk Lutsk National Technical University, Lutsk, Ukraine https://orcid.org/0000-0002-1988-5027
Tetiana O. Narozhna Zinkiv Support Lyceum No. 1 of Zinkiv City Council, Ukraine https://orcid.org/0009-0000-3262-9557

DOI: https://doi.org/10.26565/2312-4334-2025-3-46

Keywords: Water disinfection, Electron beam, Bremsstrahlung, Induced activity, Photonuclear reactions, Computer simulation, Sub-threshold energy

Abstract

The challenge of providing safe and clean drinking water requires reliable disinfection methods. Electron beam processing is a promising technology, but its industrial application is often limited by regulatory constraints, which typically cap the electron energy at 10 MeV to prevent induced radioactivity. This paper presents a theoretical justification for the radiological safety of using a higher, sub-threshold energy regime. This paper proposes operating in the 10–15.6 MeV range (using 14.9 MeV as a case study) and demonstrate that this approach allows for the treatment of significantly thicker water layers compared to the standard 10 MeV regime, while ensuring radiological safety. A comprehensive numerical model was used to simulate the process, calculating the bremsstrahlung photon spectrum and the induced activity from potential photonuclear reactions. A quantitative analysis of induced activity was performed for the main components of water (¹⁶O, ²H) and typical trace impurities according to Ukrainian standards (DSanPiN 2.2.4-171-10). The analysis proves that the induced radioactivity is negligible. The primary activation channel on oxygen is energetically forbidden, and the activity from trace elements is short-lived and falls far below the intervention levels set by Ukrainian radiation safety norms (NRBU-97). This work provides a strong physics-based rationale that a high-energy, sub-threshold regime is radiologically safe, which allows for a reconsideration of existing energy limitations in the design of electron beam water treatment facilities.

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