High-TemperatureResistance, Lightweight, and ThermallyInsulating Silica Aerogel via Doping Hollow Silica Nanoparticles

Abstract

Pure silica (SiO₂) aerogels are highly susceptible to sintering and nanopore collapse at elevated temperatures, which limits their thermal stability. Traditional solutions to this issue, such as doping with opacifiers or fibers, often increase thermal conductivity and density. To increase the thermal stability of standard aerogels comprising small full-density SiO₂ nanoparticles (SFPs) (typically 2–15 nm in diameter), SiO₂ aerogels were doped with large hollow SiO₂ nanoparticles (LHPs) with diameters of 100–250 nm. In situ transmission electron microscopy heating experiments were performed to observe the sintering behavior of SFPs and the antisintering properties of LHPs. At 1000 °C, LHPs with diameters of >120 nm and thicknesses of >22 nm retained their structural integrity, whereas substantial sintering was observed in the standard SFPs. Transient nanoparticle structural evolution was used to investigate the mechanisms underlying these phenomena. The results were validated using molecular dynamics simulations, which showed excellent agreement with the experimental results. Compared with SiO₂ aerogels doped with Al₂O₃–SiO₂ or zirconia fibers, the LHP-doped SiO₂ aerogels (0.1 wt % LHPs) exhibited remarkable performance improvements. A 71% reduction in density was achieved under ambient conditions. Furthermore, at 1100 °C, thermal conductivity decreased by 34.4%, and the density was only 242 kg/m³, the lowest density among SiO₂-based aerogel composites. This effectively overcomes the conventional trade-off among high-temperature resistance, thermal insulation, and low density. This study presents a cost-effective and resource-efficient approach for developing lightweight thermal insulation materials for high-temperature applications.