Group Representation of the Formation Probabilities of Athermal Vacancy Clusters in Atomic Collision Cascades

“…Moreover, from [17] follows that decreasing the primary knock-out atom (PKA) energy results in the increase of vacancies entering athermal divacancies. I n particular, if PKA can create only two Prenkel pairs, then half of the appearing athermal vacancies will be of the form of divacancies.…”

“…It is well known [I] that vacancy loops in nickel are observed a t irradiation temperatures 250 to 450 "C, which is less than the lower temperature boundary of swelling. Moreover, from [17] follows that decreasing the primary knock-out atom (PKA) energy results in the increase of vacancies entering athermal divacancies. I n particular, if PKA can create only two Prenkel pairs, then half of the appearing athermal vacancies will be of the form of divacancies.…”

Small Vacancy Clusters in Nickel

“…Moreover, from [17] follows that decreasing the primary knock-out atom (PKA) energy results in the increase of vacancies entering athermal divacancies. I n particular, if PKA can create only two Prenkel pairs, then half of the appearing athermal vacancies will be of the form of divacancies.…”

“…It is well known [I] that vacancy loops in nickel are observed a t irradiation temperatures 250 to 450 "C, which is less than the lower temperature boundary of swelling. Moreover, from [17] follows that decreasing the primary knock-out atom (PKA) energy results in the increase of vacancies entering athermal divacancies. I n particular, if PKA can create only two Prenkel pairs, then half of the appearing athermal vacancies will be of the form of divacancies.…”

Small Vacancy Clusters in Nickel

Displacement Spike Annealing in α‐Iron Irradiated by PKA in the Energy Range 20 to 100 keV

Defect clusters and subcascades. II. The splitting threshold and subcascade dimensions