Ultralow Thermal Conductivity and Excellent Gamma-Radiation Resistance of a Novel Boron-Doped Silica Aerogel for Thermal Protection in Nuclear Applications

Silica (SiO2) aerogels have been considered as promising materials for thermal insulation. However, SiO2 aerogels' poor high-temperature stabilities, mechanical properties, and radiation resistances mean that their application as thermal insulation materials in nuclear power is greatly limited. In this study, novel boron (B)-doped SiO2 aerogels were prepared by a sol-gel process, and the aerogel with a Si/B molar ratio of 1:0.15 was found to exhibit excellent radiation resistance and low thermal conductivity. Specifically, investigations of the microstructure and performance changes of the B-free SiO2 aerogel and B-doped SiO2 aerogels after exposure to gamma (gamma)-radiation revealed that the latter were more resistant than the former to gamma-radiation. However, B-doped SiO2 aerogels containing low concentrations of B3+ were damaged by high cumulative doses of gamma-radiation, whereas those containing high concentrations of B3+ tended to undergo oxidation and thus contained boron trioxide. A B-doped SiO2 aerogel with a Si/B molar ratio of 1.00:0.15 exhibited excellent structural stability and gamma-radiation resistance, even when exposed to a high cumulative dose of gamma-radiation (1700 kGy). Moreover, this B-doped SiO2 aerogel exhibited desirable thermal conductivity (0.0147 W/m K at 25 degrees C), hydrophobicity, and high temperature resistance (3 mu m infrared transmittance of 39.52%), even after gamma-irradiation. In summary, these findings suggest that B-doped SiO2 aerogels warrant exploration for use as thermal insulation materials for pipelines in nuclear power plants. It provides valuable insights for the study of the radiation effects of aerogel materials in nuclear power applications.