Open AccessThe basics of radiation damage in crystalline silicon networks by NIEL
Author(s) -
Carla Daruich de Souza,
Jin Joo Kim,
Jin Tae Hong
Publication year - 2021
Publication title -
brazilian journal of radiation sciences
Language(s) - English
Resource type - Journals
ISSN - 2319-0612
DOI - 10.15392/bjrs.v9i3.1707
Subject(s) - silicon , ionization , radiation damage , radiation , crystalline silicon , materials science , detector , lattice (music) , lattice vibration , nuclear engineering , atomic physics , forensic engineering , engineering physics , nuclear physics , optoelectronics , physics , optics , condensed matter physics , phonon , engineering , ion , acoustics , quantum mechanics
Basically, radiation can cause two effects on materials: ionization and non-ionization. This work presented the theory involved in defects caused by non-ionization, known as NIEL, with a focus on silicon materials. When energy is transferred directly to the atoms in the crystalline lattice, it can either be dissipated in the form of vibrations or be large enough to pull atoms out of that lattice. This weakens the lattice, causing measurement errors that can lead to permanent damage. This study is extremely important because silicon materials are used in radiation detectors. These detectors cannot return false measurements, especially in dangerous situations, such as in nuclear reactor monitoring. After presenting the theory involved, examples are shown. Failures of up to 30% were found by the researchers.