First-principles study of beryllium thermodynamics and clustering mechanism in molybdenum: Effects of vacancies and self-interstitial atoms

First-principles study of beryllium thermodynamics and clustering mechanism in molybdenum: Effects of vacancies and self-interstitial atoms

The clustering behavior of beryllium (Be) following plasma irradiation is of particular significance for molybdenum (Mo) in future fusion devices. Using first-principles calculations combined with thermodynamic models, the optimal configuration for Be clustering in Mo has been clearly determined, wi...

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Bibliographic Details
Main Authors: Aoyu Mo, Haijun Li, Fuquan Guo, Xiaowei Ma, Yunshan Xiong, Peng Shao, Bo Li, Kun Jie Yang, Yue-Lin Liu, Quan-Fu Han
Format: Article
Language:English
Published: Elsevier 2025-06-01
Series:Nuclear Materials and Energy
Subjects:
Molybdenum
Beryllium
Vacancy
Self-interstitial atom
First-principles calculations
Online Access:http://www.sciencedirect.com/science/article/pii/S2352179125000900
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Summary:The clustering behavior of beryllium (Be) following plasma irradiation is of particular significance for molybdenum (Mo) in future fusion devices. Using first-principles calculations combined with thermodynamic models, the optimal configuration for Be clustering in Mo has been clearly determined, with a particular focus on the effects of vacancies and self-interstitials (SIAs). As the initial form of nucleation, the physical origin of Be-Be pair binding energy in Mo has been shown to be primarily dominated by the charge density at their location. Based on all of our computational results, a potential clustering mechanism for the formation of Be-rich regions in Mo is proposed: Be atoms first aggregate at interstitial sites, forming Ben clusters. When the number of Be atoms reaches six, they form an approximately “octahedral” structure, displacing a central Mo atom and generating a Be6V cluster and an SIA. They act as nucleation sites that continue to attract more Be atoms, growing into larger BenV and Ben-SIA clusters. As the Ben-SIA clusters expand, excess Be atoms displace more Mo atoms, creating additional SIAs and vacancies and further propagating the formation of Ben-SIA and BenV clusters. This cascading process ultimately results in the development of Be-rich regions within Mo. Our results provide significant data support for advancing Mo as a primary mirror material and also offer valuable theoretical insights into the aggregation behavior of impurities in metals under irradiation conditions.
ISSN:2352-1791

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