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Main Authors: Shvydka, Diana, Karpov, Victor
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.10786
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author Shvydka, Diana
Karpov, Victor
author_facet Shvydka, Diana
Karpov, Victor
contents We develop a quantitative model of ionization processes in biological tissues under Ultra High Dose Rate (UHDR) radiation. The underlying conjecture is that of electron-hole liquid (EHL) forming in water based substances of biological tissues. Unlike the earlier known EHL in semiconductor crystals, the charge carriers here are low mobile due to strong interactions with the background (solvated electrons, etc.); hence, EHL resembling ionic melts. Similar to all ionic systems, the Coulomb coupling makes that EHL energetically favorable that leads to recombination barriers suppressing subsequent structural transformations. In particular, generation of secondary reactive species in such EHL becomes limited translating into reduction of biological damages and tissue sparing effect. We show how these processes are sensitive to the tissue quality and frequency dispersion of the dielectric permittivity. Equations for dose and dose rate defining the sparing thresholds are derived.
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id arxiv_https___arxiv_org_abs_2510_10786
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publishDate 2025
record_format arxiv
spellingShingle Electron-hole liquid in biological tissues under ultra high dose rate ionizing radiation
Shvydka, Diana
Karpov, Victor
Materials Science
Biological Physics
Medical Physics
We develop a quantitative model of ionization processes in biological tissues under Ultra High Dose Rate (UHDR) radiation. The underlying conjecture is that of electron-hole liquid (EHL) forming in water based substances of biological tissues. Unlike the earlier known EHL in semiconductor crystals, the charge carriers here are low mobile due to strong interactions with the background (solvated electrons, etc.); hence, EHL resembling ionic melts. Similar to all ionic systems, the Coulomb coupling makes that EHL energetically favorable that leads to recombination barriers suppressing subsequent structural transformations. In particular, generation of secondary reactive species in such EHL becomes limited translating into reduction of biological damages and tissue sparing effect. We show how these processes are sensitive to the tissue quality and frequency dispersion of the dielectric permittivity. Equations for dose and dose rate defining the sparing thresholds are derived.
title Electron-hole liquid in biological tissues under ultra high dose rate ionizing radiation
topic Materials Science
Biological Physics
Medical Physics
url https://arxiv.org/abs/2510.10786