Reactivity and deuterium retention properties of titanium-beryllium intermetallic compounds

Abstract Beryllium intermetallic compounds (beryllides), such as Be 12 Ti and Be 12 V, are the most promising advanced neutron multipliers in demonstration (DEMO) fusion power reactors because of higher stability, lower retention, and swelling. The advanced neutron multipliers are being developed by Japan and the EU as a framework of Broader Approach (BA) activities, targeted at broadening the research fields to not only establish fabrication methods but also for their characterization. Our group has proposed a plasma sintering method for the synthesis of beryllides. When the mixed powder was plasma-sintered at the beginning of the experiment, consolidation of the target composition was so insufficient that single-phase beryllides could not be synthesized. In order to obtain single-phase beryllides, an additional homogenization treatment of the sintered beryllides at 1473 K was necessary, resulting in increased porosity. Using the homogenized powder as the starting material, single-phase Be 12 Ti and Be 17 Ti 2 intermetallic compounds were successfully synthesized. As experimental results, the hardness of the compounds was relatively low owing to low sintering density. In addition, the oxidation behavior of the beryllides, when exposed to 15% H 2 O/Ar at high temperatures, were investigated and the results indicate the presence, gray colored Be oxide formed on the surface in Be 12 Ti tested at above 1073 K and Be oxide with a small fraction of white colored Ti oxide even tested at 873 K in Be 17 Ti 2 phase resulting in the bigger increase of the weight gain than Be 12 Ti. In addition, this oxidation occurring at lower temperature can be reasoned by the assumption that the existence of BeO (=oxygen content) in Be 12 Ti (1.95%) and Be 17 Ti 2 (2.95%) may facilitate increased reactivity. Furthermore, thermal expansion of Be 17 Ti 2 was found out to be bigger than that of Be 12 Ti because Be 17 Ti 2 has more complex crystal structure and higher melting temperature. In terms of deuterium desorption and retention properties, the maximum peaks are detected around 600 K in beryllides, while those in beryllium occur at 800 and 980 K. From the comparison of deuterium retention, it was obvious that Be 17 Ti 2 has a lower retention than Be 12 Ti, while Be has the highest value.