Theory of superplasticity in polycrystalline materials: Stress-induced structural instabilities of grain boundaries
Author
dc.contributor.author
Lagos, Miguel
Admission date
dc.date.accessioned
2018-12-20T14:11:13Z
Available date
dc.date.available
2018-12-20T14:11:13Z
Publication date
dc.date.issued
2005
Cita de ítem
dc.identifier.citation
Physical Review B - Condensed Matter and Materials Physics, Volumen 71, Issue 22, 2018,
Identifier
dc.identifier.issn
10980121
Identifier
dc.identifier.issn
1550235X
Identifier
dc.identifier.other
10.1103/PhysRevB.71.224117
Identifier
dc.identifier.uri
https://repositorio.uchile.cl/handle/2250/154507
Abstract
dc.description.abstract
A fine mechanical analysis of a polycrystalline material subjected to large stresses must distinguish between intergranular and crystalline matter because they have different mechanical properties. Homogeneity is an illusion at the grain level. It is shown that a grain boundary under the action of a strong enough in-plane shear stress becomes unstable, buckling into periodic trenches or a corrugated profile. The former should always occur; the latter demands the existence of steps, intersecting hard particles or triple junctions. Strongly varying stress fields, spontaneously induced to preserve mechanical equilibrium at the grain scale, cause intergranular matter to begin to release and capture vacancies in alternate sectors. The subsequent active lattice diffusion near the buckled boundary causes adjacent crystallites to slide. The effect is translated into the macroscopic scale to derive a closed-form constitutive equation relating stress, strain rate, temperature, grain size, and gr