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Insights into the primary radiation damage of silicon by a machine learning interatomic potential

A. Hamedani, Jesper Byggmästar, Flyura Djurabekova, Ghasem Alahyarizadeh, Reza Ghaderi, A. Minuchehr, K. Nordlund

2020Materials Research Letters32 citationsDOIOpen Access PDF

Abstract

We develop a silicon Gaussian approximation machine learning potential suitable for radiation effects, and use it for the first ab initio simulation of primary damage and evolution of collision cascades. The model reliability is confirmed by good reproduction of experimentally measured threshold displacement energies and sputtering yields. We find that clustering and recrystallization of radiation-induced defects, propagation pattern of cascades, and coordination defects in the heat spike phase show striking differences to the widely used analytical potentials. The results reveal that small defect clusters are predominant and show new defect structures such as a vacancy surrounded by three interstitials.

Topics & Concepts

Materials scienceRadiation damageSiliconInteratomic potentialIrradiationAb initioRadiationSputteringMolecular physicsCrystallographic defectCluster analysisChemical physicsAtomic physicsMolecular dynamicsOptoelectronicsCondensed matter physicsNanotechnologyOpticsComputational chemistryThin filmComputer sciencePhysicsMachine learningNuclear physicsChemistryQuantum mechanicsMachine Learning in Materials ScienceNuclear Materials and PropertiesSilicon and Solar Cell Technologies
Insights into the primary radiation damage of silicon by a machine learning interatomic potential | Litcius