The mechanical strength of many glasses and ceramic materials decreases with time under static loading and ambient environments. This strength loss is associated with slow growth of pre-existing surface flaws due to a stress-corrosion process. To make long-term strength predictions for ceramic components, it is important to understand the stress-corrosion mechanism. We have studied stress corrosion in vitreous silica exposed to water and several non-aqueous environments and report here that environments which enhance stress corrosion are composed of molecular groups with electron donor sites on one end and proton donor sites at the other. These results suggest a detailed chemical model for the interaction of the environment with mechanically strained bonds in the solid at the tip of a crack. The proposed model also has implications for the long-term strength behaviour of a wide variety of brittle materials.
[1]
Keith J. Laidler,et al.
Theories Of Chemical Reaction Rates
,
1969
.
[2]
Edwin R. Fuller,et al.
Micromechanisms of crack growth in ceramics and glasses in corrosive environments
,
1980
.
[3]
P. W. Mast,et al.
Crack propagation studies in brittle materials
,
1973
.
[4]
E. Orowan.
The Fatigue of Glass Under Stress
,
1944,
Nature.
[5]
U. F. Zackay.
High-strength Materials
,
1965
.
[6]
S. Wiederhorn,et al.
Stress Corrosion and Static Fatigue of Glass
,
1970
.