Corrosion of electron-irradiated Zr-2.5Nb and Zircaloy-2

We used 10-MeV electrons to rapidly produce radiation damage in zirconium alloys, investigated whether electrons produced the same microstructural changes as neutrons, then performed post-irradiation corrosion tests to determine whether electron-irradiated materials displayed similar corrosion behavior to neutron-irradiated materials. Two irradiations were completed using 10-MeV electrons with the beam normal to thin disks of material of a diameter slightly larger than the beam. The beam distribution and disk cooling were designed to produce radial temperature and dose distributions having maxima at the disk center. A high-temperature irradiation was performed on annealed Zr-2.5Nb disks, achieving a central dose of 1.3 dpa and at a central temperature of approximate to 450 degrees C. After irradiation, the samples contained needle-like beta-Nb precipitates in the alpha-Zr matrix similar to those produced by neutrons. A low-temperature irradiation was pi-formed on half-moon disks of Zr-2.5Nb and Zircaloy-2 pressure tube materials at 310 degrees C central temperature and 1.3-dpa central dose. Dislocation loops were observed, again similar to those produced in neutron-irradiated materials. Some of the high-temperature electron-irradiated disks were exposed to 300 degrees C moist air (saturated with D2O), and in separate tests, high- and low-temperature irradiated disks were corroded in 300 degrees C D2O (11.0 pD at room temperature) in an autoclave. Measurements of oxide thickness by Fourier Transform Infrared Reflectance (FTIR) spectroscopy showed that electron irradiation reduced the corrosion rate of Zr-2,5Nb compared with that of unirradiated material, as observed for neutron irradiation. For exposures to moist air and to D2O, the theoretical deuterium uptakes for the electron-irradiated materials were, respectively, about 4 times and 1.5 to 2 times those for the unirradiated materials. This is also in good agreement with results for neutron-irradiated pressure tube materials. Thus, 10-MeV electrons produced the same corrosion behavior as fast neutrons in post-irradiation corrosion tests of Zr-2.5Nb pressure tube materials. For Zircaloy 2, the corrosion rates were the same for both electron-irradiated and unirradiated materials, similar to those observed for neutron-irradiated Zircaloy-4.