Ab initio simulations of the structure, energetics and mobility of radiation-induced point defects in bcc Nb

The formation, binding and migration energetics of helium clusters inside a niobium crystal have been analysed via ab initio simulations. The effect of placing several He atoms within an n-vacancy previously formed or as interstitials inside the initial perfect bulk matrix has been studied. DFT-base...

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Bibliographic Details
Published inJournal of nuclear materials Vol. 478; pp. 185 - 196
Main Authors Cerdeira, M.A., Palacios, S.L., González, C., Fernández-Pello, D., Iglesias, R.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.09.2016
Subjects
DFT
Formation energy
He clustering
Migration
n-vacancies
Niobium
Formation energy
DFT
He clustering
n-vacancies
Migration
Niobium
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Summary:The formation, binding and migration energetics of helium clusters inside a niobium crystal have been analysed via ab initio simulations. The effect of placing several He atoms within an n-vacancy previously formed or as interstitials inside the initial perfect bulk matrix has been studied. DFT-based results show that He atoms prefer to aggregate forming small clusters at n-vacancy sites rather than at interstitial positions in the perfect crystal. The minimum formation energy is found when NHe is equal to the number of vacancies, n. It follows that vacancies act as almost perfect traps for He atoms, as is well known for other metals. The migration barriers of He atoms inside vacancies increase considerably when compared to what happens for vacancies alone. A secondary consequence is that the full set of energies obtained will be highly relevant as an input for new approaches to KMC simulations of defects in Nb.
ISSN:0022-3115
1873-4820
DOI:10.1016/j.jnucmat.2016.06.013