Effects of Re Content and Fabrication Process on Microstructural Changes and Hardening in Neutron Irradiated Tungsten

Abstract

The effects of the material fabrication process and rhenium (Re) content on the irradiation-induced changes in the microstructure and hardness of pure tungsten (W) and W­Re alloys were investigated. Neutron irradiation of pure W and W­Re alloys (Re concentration 3­26%) was carried out in the experimental fast reactor JOYO. The irradiation conditions were 0.44 displacement per atom (dpa) at 531°C and 0.47dpa at 583°C for pure W and W­Re alloys, respectively. After irradiation, microstructural observations using a transmission electron microscope (TEM) and Vickers microhardness tests were performed. Voids and dislocation loops were observed in both pure W and W­Re alloys after irradiation. The number density of voids in pure W was higher than that in W­3%Re, W­5%Re and W­10%Re. Only in the case of W­26%Re irradiated to 0.47dpa at 583°C were there no voids observed, but irradiation-induced fine precipitates and a few dislocation loops were observed. The irradiation hardening of pure W was greater than that of the W­Re alloys. It was considered that irradiation hardening of pure W was caused mainly by the higher number density of voids. The addition of Re suppressed void formation and irradiation hardening of the W­Re alloys. Irradiation hardening of W was also suppressed in hot-rolled W compared with arc-melted as-cast W. [doi:10.2320/matertrans.MBW201110]