Verification of the theory of primary radiation damage by comparison with experimental data

“…It was shown that 22.5 MeV protons produce mono-vacancies in W but the neutrons from the p(35 MeV)-Be generator produce vacancy clusters with an average size of 3–5 vacancies during irradiation at ambient temperature up to a fluence of 1.4 × 10 20 n/m 2 (corresponding to about 9 appm of the NRT-dpa). In the present paper, we extend the pioneer work 14 by comparing the cluster size of vacancy-type defects formed in W and Fe after irradiation with fission and wide-spectrum high energy neutrons.…”

“…located close to each other. Agglomeration of such vacancies into clusters is relatively easy, since it does not require diffusion to a long distance 14 .…”

“…Unlike low-Z materials, for example Fe, which require irradiation and subsequent measurement at cryogenic temperatures in order to neglect the impact of thermal effects on the defect recovery 30 , W has the advantage of high melting temperature and, therefore, migration of vacancy-type defects is insignificant even at 400 K. Since migration of interstitials occurs at significantly lower temperatures compared to vacancies, some vacancy-type defects in W were likely removed by recombination with migrating interstitials which are mobile well below room temperature.

Figure 4 Experimental data of the mean size of radiation-induced vacancy clusters in W and their density after irradiation in the LVR-15 reactor in comparison with high-energy p(35 MeV)-Be neutron irradiation 14 for each irradiation fluence indicated for the NRT-dpa values in appm.

…”

“…A recent paper 14 compared radiation-induced defects in W and iron (Fe) irradiated with high-energy protons and neutrons. Positron annihilation lifetime spectroscopy (PALS) was employed for characterization of size and concentration of radiation-induced defects 15 .…”

“…In the work 14 , it was shown that experimental data for neutron- and proton-irradiated Fe are better described by the arc-dpa model than the NRT-dpa model. Whereas experimental data for neutron- and proton-irradiated W are between NRT-dpa and arc-dpa predictions.…”

Positron annihilation spectroscopy study of radiation-induced defects in W and Fe irradiated with neutrons with different spectra

“…It was shown that 22.5 MeV protons produce mono-vacancies in W but the neutrons from the p(35 MeV)-Be generator produce vacancy clusters with an average size of 3–5 vacancies during irradiation at ambient temperature up to a fluence of 1.4 × 10 20 n/m 2 (corresponding to about 9 appm of the NRT-dpa). In the present paper, we extend the pioneer work 14 by comparing the cluster size of vacancy-type defects formed in W and Fe after irradiation with fission and wide-spectrum high energy neutrons.…”

“…located close to each other. Agglomeration of such vacancies into clusters is relatively easy, since it does not require diffusion to a long distance 14 .…”

“…Unlike low-Z materials, for example Fe, which require irradiation and subsequent measurement at cryogenic temperatures in order to neglect the impact of thermal effects on the defect recovery 30 , W has the advantage of high melting temperature and, therefore, migration of vacancy-type defects is insignificant even at 400 K. Since migration of interstitials occurs at significantly lower temperatures compared to vacancies, some vacancy-type defects in W were likely removed by recombination with migrating interstitials which are mobile well below room temperature.

Figure 4 Experimental data of the mean size of radiation-induced vacancy clusters in W and their density after irradiation in the LVR-15 reactor in comparison with high-energy p(35 MeV)-Be neutron irradiation 14 for each irradiation fluence indicated for the NRT-dpa values in appm.

…”

“…A recent paper 14 compared radiation-induced defects in W and iron (Fe) irradiated with high-energy protons and neutrons. Positron annihilation lifetime spectroscopy (PALS) was employed for characterization of size and concentration of radiation-induced defects 15 .…”

“…In the work 14 , it was shown that experimental data for neutron- and proton-irradiated Fe are better described by the arc-dpa model than the NRT-dpa model. Whereas experimental data for neutron- and proton-irradiated W are between NRT-dpa and arc-dpa predictions.…”

Positron annihilation spectroscopy study of radiation-induced defects in W and Fe irradiated with neutrons with different spectra

Trends in vacancy distribution and hardness of high temperature neutron irradiated single crystal tungsten

RDM: An R interface for high-throughput simulation of ion-material interactions using TRIM