Takashi Tanno scite author profile

Tungsten (W) is a candidate material for Plasma facing materials of fusion reactors. During fusion reactor operation, not only irradiation damages but also transmutation elements such as rhenium (Re) and osmium (Os) are produced by neutron irradiation. As a result, the original pure tungsten changes to W-Re or W-Re-Os alloys. Thus, the mechanical and physical properties are expected to change. The aim of this study is to investigate the effects of transmutation elements on neutron irradiation hardening and microstructure changes of tungsten.To simulate the effects of transmutation elements, tungsten base model alloys were used in this study. The examined compositions of the alloys were selected from the calculated changes in solid solution area of W-Re-Os alloy. Neutron irradiation was performed in fast test reactor JOYO in JAEA. The irradiation damages and temperature ranges were 0.17-1.54 dpa and 400-750 C respectively. After the irradiation, Vickers hardness test and TEM observation were performed.There were clear differences between Re and Os in effects on irradiation hardening. In the case of W-Re alloys, when damages were less than 0.40 dpa, the irradiation hardenings were nearly equal to those of pure tungsten independent of Re addition. But when the damage was 1.54 dpa, the irradiation hardenings increased lineally with Re content. Microstructural observations showed that precipitations mainly formed in W-Re alloys. In the case of W-Os alloys, the irradiation hardenings (ÁHv) of W-3Os alloys were larger than those of pure tungsten. And the differences were about 400 independent of dpa and irradiation temperature. Effects of Re and Os on irradiation hardening based on the microstructural observations were discussed.

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Microstructure Development in Neutron Irradiated Tungsten Alloys

Tanno

et al. 2011

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The aim of this work is to investigate the influence of neutron irradiation condition, especially temperature, on irradiation hardening and microstructure development in irradiated tungsten-rhenium (W-Re) alloys. Neutron irradiations were carried out in JOYO at the range of 400 to 750 C, up to 1.54 dpa. Micro Vickers hardness tests and micro structural observations using a TEM were performed. Irradiation hardening of WRe alloys irradiated at 538 C were clearly larger than those irradiated at other temperatures. Fine voids and fine needle-or plate-like precipitates were observed in pure W and W-Re alloys irradiated at 538 C, respectively, with high number density. The fine complex microstructure seems to be the cause of the characteristic irradiation hardening.

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Effects of transmutation elements on the microstructural evolution and electrical resistivity of neutron-irradiated tungsten

Tanno

Hasegawa

et al. 2009

Journal of Nuclear Materials

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Takashi Tanno

Effects of Transmutation Elements on Neutron Irradiation Hardening of Tungsten

Microstructure Development in Neutron Irradiated Tungsten Alloys

Effects of transmutation elements on the microstructural evolution and electrical resistivity of neutron-irradiated tungsten

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