This paper describes the use of simulation techniques to examine some of the processes involved in the alignment of voids under the influence of 1-dimensional self-interstitial atom transport. The work follows the paper of Heinisch and Singh but a different and simpler methodology was used. Besides repeating the scenarios studied by Heinisch and Singh, the effects of re-nucleation and the influence of vacancies were introduced. One of the important processes that emerged from the results was the barrier to precise void alignment caused by the self-interstitial atom-induced coalescence of aligned voids. This appears to prevent the formation of stable void lattices by any 1D self-interstitial atom transport mechanism, a point supported by the initial void alignment in the mechanism requiring swelling values well above those found experimentally. A full consideration of the void lattice phenomenon showed that the one-dimensional diffusion of self-interstitials central to the production bias model of irradiation damage cannot be the only mode of anisotropic diffusion available under irradiation.

Simulations of the Effects of 1D Interstitial Diffusion on Void Lattice Formation during Irradiation. J.H.Evans: Philosophical Magazine, 2005, 85[11], 1177-90