Mechanisms of progressive degradation in ion-exchanged boroaluminosilicate glass: A comparative study

While the environmental durability of chemically strengthened alkali-boroaluminosilicate glass is paramount for consumer electronics, the mechanistic coupling between residual ion-exchange stress profiles and surface weathering kinetics remains poorly defined. This study presents a comparative analysis of the degradation mechanisms in ion-exchanged Corning® Gorilla® Glass 3 (I-GG3) and its native precursor (N-GG3) subjected to accelerated weathering protocols. N-GG3 follows a gel densification model, characterized by spontaneous repolymerization and syneresis during dry cycles, processes catalyzed by the hydrolytic stability of the residual aluminosilicate network. The volumetric shrinkage associated with this densification, constrained by the underlying bulk substrate, generates localized tensile stress fields that drive stochastic pitting. Conversely, I-GG3 undergoes network depolymerization driven by the thermodynamic instability and high chemical potential of the potassium-enriched surface. Rapid alkali leaching triggers a localized alkaline attack that selectively depletes intermediate network formers (Al, Mg), inhibiting densification and yielding a porous hydrogel layer. Despite the formation of this hydrated layer, the residual compressive stress profile suppresses vertical crack propagation, promoting a uniform dissolution regime that preserves optical transmission and bulk damage tolerance.