Evolution from transparent SiO2 glass to ceramics enabled by cold sintering with a transient chemistry: H2SiO3

Abstract

Silica (SiO2) glass has a wide range of industrial applications due to its outstanding optical, physicochemical, and electrical properties. Herein, a transparent SiO2 glass with a high relative density of 96.8% is fabricated at 200 °C by cold sintering with a transient chemistry of H2SiO3, and a visible light transmittance of ∼80%, Vickers hardness of 3.1 (±0.14) GPa and Young's modulus of 45.6 (±2.7) GPa are achieved. Moreover, it is found that the transition from glass phase to crystallized ceramic occurs between 200 oC and 300 °C during the cold sintering process. The microstructural analysis shows an obvious phenomenon of recrystallization, accompanying by a formation of polygonal α-quartz grains of ∼150 nm. Meanwhile, the α-quartz ceramic presents an enhanced Vickers hardness and Young's modulus of 5.7 (± 0.13) and 60.2 (± 3.2) GPa, respectively. This work provides an efficacious way for designing SiO2 glass and ceramics at low sintering temperatures.