Abstract
Atomic-scale computer simulation has been used to study the thermally activated atomic transport of self-interstitial atoms (SIAs) in the form of planar clusters in pure Cu and α-Fe. There is strong evidence that such clusters are commonly formed in metals during irradiation with high-energy particles and play an important role in accumulation and spatial distribution of surviving defects. An extensive study of the mobility of SIA clusters containing two to 331 interstitials has been carried out using the molecular dynamics simulation technique for the temperature range from 180 to 1200 K. The results obtained show that clusters larger than three to four SIAs are one-dimensionally mobile in both Cu and Fe. Large clusters of more than 100 SIAs in Cu and 300 SIAs in Fe have significantly reduced mobility. The problem of describing one-dimensional (1D) motion in three-dimensional space is discussed. An attempt is made to describe the mobility of SIA clusters within the approximation of 1D diffusion. For clusters in both metals the effective migration energy of 1D diffusion as estimated via the jump frequency of the cluster centre of mass is found to be independent of the number of SIAs in the clusters, although the cluster jump frequency decreases with increasing cluster size. Mechanisms of 1D mobility of interstitial clusters are discussed.
Original language | English |
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Pages (from-to) | 61-91 |
Number of pages | 31 |
Journal | Philosophical Magazine |
Volume | 83 |
Issue number | 1 |
DOIs | |
State | Published - Jan 1 2003 |
Externally published | Yes |
Funding
ACKNOWLEDGEMENTS We are grateful to Professor A. Lidiard, Dr H. Trinkaus, Dr A. Barashev and Dr F. Gao for numerous discussions. Yu N. O. is grateful to Dr G. Morello Castro for help during preparation of the manuscript. B.N.S. would like to acknowledge partial support from the European Fusion Programme. The computational work was done at the Centre de Supercomputacio de Catalunya under the ‘Access to Supercomputing Facilities for European Researchers’, a project of the Large Scale Facilities programme (contract ERBCHGE-CT92-0009) and supported by the UK Engineering and Physical Sciences Research Council, University of Liverpool and PB96-0170-C03 project of the Spanish DGI.