Nanoscopic structure of borosilicate glass with additives for nuclear waste vitrification

We investigated the nanoscopic structure of bomsilicate glasses as a host for high-level radioactive liquid waste (HLLW) in the presence of the additives Na2O and CaO/ZnO with and without Li2O. These additives have been used to lower the glass melting point, suppress the macroscopic phase separation, and increase the chemical durability of glasses. Small-angle neutron scattering was used to elucidate the effect of the additives on the nanoscopic structure along with macro- and atomic-scale observations obtained using neutron imaging and X-ray diffraction, respectively. The borosilicate glass made without Na2O formed a microphase-separated structure of SiO2- and B2O3-rich domains approximately 100 nm in size, and the material was homogeneous at length scales up to millimeters. With the addition of increasing amounts of Na2O, the domain spacing decreased. Introducing CaO/ZnO additives induced inhomogeneities in the glass, such as void structures several nanometers in size, although the inhomogeneity was suppressed by the coaddition of Li2O. These results provide insights into the performance of host glasses for HLLW vitrification. Incorporating HLLW into glasses is likely to cause changes in the nanoscopic structure of host glasses similar to those revealed here.

Automated summary

This study investigates the impact of additives on the nanoscopic structure of borosilicate glasses. The results show that Na2O decreases the glass melting point and increases the spacing of SiO2 and B2O3-rich domains, while CaO/ZnO additives induce void structures in the glass, which can be suppressed by Li2O.