Figure 5 Increase in NDT Temperatures of Steels from Irradiation Below 232°C

EFFECT DUE TO NEUTRON CAPTURE DOE-HDBK-1017/2-93 Plant Materials Figure 5 Increase in NDT Temperatures of Steels from Irradiation Below 232°C The generally accepted explanation of irradiation-induced swelling is based on the characteristics of interstitial loops and voids or vacancy loops. If the temperature is high enough to permit interstitials and vacancies, but not high enough to allow recombination, a relatively large (supersaturated) concentration of defects can be maintained under irradiation. Under these circumstances, the interstitials tend to agglomerate, or cluster, to form roughly circular two- dimensional disks, or platelets, commonly called interstitial loops. A dislocation loop is formed when the collapse (or readjustment) of adjacent atomic planes takes place. On the other hand, vacancies can agglomerate to form two-dimensional vacancy loops, which collapse into dislocation loops, or three-dimensional clusters called voids. This difference in behavior between interstitials and vacancies has an important effect on determining the swelling that many metals suffer as a result of exposure to fast neutrons and other particle radiation over a certain temperature range. When irradiation-induced swelling occurs, it is usually significant only in the temperature range of roughly 0.3 T_m to 0.5 T_m, where T_m is the melting point of the metal in Kelvin degrees. MS-05 Page 42 Rev. 0