Your search keyword '"Neutrons adverse effects"' showing total 2 results

1. Evaluating the risk of data loss due to particle radiation damage in a DNA data storage system.

Author

Takahashi CN, Ward DP, Cazzaniga C, Frost C, Rech P, Ganguly K, Blanchard S, Wender S, Nguyen BH, and Smith JA

Subjects

Neutrons adverse effects, DNA Damage radiation effects, Information Storage and Retrieval methods, Radiation, Ionizing, Kinetics, DNA radiation effects

Abstract

DNA data storage is a potential alternative to magnetic tape for archival storage purposes, promising substantial gains in information density. Critical to the success of DNA as a storage media is an understanding of the role of environmental factors on the longevity of the stored information. In this paper, we evaluate the effect of exposure to ionizing particle radiation, a cause of data loss in traditional magnetic media, on the longevity of data in DNA data storage pools. We develop a mass action kinetics model to estimate the rate of damage accumulation in DNA strands due to neutron interactions with both nucleotides and residual water molecules, then utilize the model to evaluate the effect several design parameters of a typical DNA data storage scheme have on expected data longevity. Finally, we experimentally validate our model by exposing dried DNA samples to different levels of neutron irradiation and analyzing the resulting error profile. Our results show that particle radiation is not a significant contributor to data loss in DNA data storage pools under typical storage conditions., (© 2024. The Author(s).)

Published

2024

2. Organ dose equivalents of albedo protons and neutrons under exposure to large solar particle events during lunar human landing missions.

Author

Pak S and Cucinotta FA

Subjects

Humans, Astronauts, Solar Activity, Radiation Protection methods, Phantoms, Imaging, Radiation Exposure analysis, Cosmic Radiation adverse effects, Neutrons adverse effects, Moon, Space Flight, Monte Carlo Method, Protons adverse effects, Radiation Dosage

Abstract

Astronauts participating in lunar landing missions will encounter exposure to albedo particles emitted from the lunar surface as well as primary high-energy particles in the spectra of galactic cosmic rays (GCRs) and solar particle events (SPEs). While existing studies have examined particle energy spectra and absorbed doses in limited radiation exposure scenarios on and near the Moon, comprehensive research encompassing various shielding amounts and large SPEs on the lunar surface remains lacking. Additionally, detailed organ dose equivalents of albedo particles in a human model on the lunar surface have yet to be investigated. This work assesses the organ dose equivalents of albedo neutrons and albedo protons during historically large SPEs in August 1972 and September 1989 utilizing realistic computational anthropomorphic human phantom for the first time. Dosimetric quantities within human organs have been evaluated based on the PHITS Monte Carlo simulation results and quality factors of the state-of-the-art NASA Space Cancer Risk (NSCR) model, as well as ICRP publications. The results with the NSCR model indicate that the albedo contribution to organ dose equivalent is less than 3 % for 1 g/cm 2 aluminum shielding, while it increases to more than 30 % in some organs for 50 g/cm 2 aluminum shielding during exposure to low-energy-proton-rich SPEs., Competing Interests: Conflict of Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024. Published by Elsevier B.V.)

Published

2024