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|dc.identifier.citation||Journal of Geophysical Research: Solid Earth, 2013; 118(5):2049-2066||en|
|dc.description||Article first published online: 23 MAY 2013||en|
|dc.description.abstract|| We analyze the propagation of compaction bands in high porosity sandstones using a constitutive model based on breakage mechanics theory. This analysis follows the work by Das et al.  on the initiation of compaction bands employing the same theory. In both studies, the theory exploits the links between the stresses and strains, and the micromechanics of grain crushing and pore collapse, giving the derived constitutive models advantages over previous models. In the current post localization analysis, the bifurcation instability of the continuum model is suppressed by the use of a rate-dependent regularization. This allows us to perform a series of finite element analyses of drained triaxial tests on porous sandstone specimens. The obtained numerical results compare well with experimental counterparts, in terms of both the initiation and propagation of compaction bands, besides the macroscopic stress-strain responses. On this basis, a parametric study is carried out to explore the effects of loading rate, degree of structural imperfections, and confining pressure on the propagation of compaction bands.||en|
|dc.description.statementofresponsibility||Arghya Das, Giang D. Nguyen, and Itai Einav||en|
|dc.publisher||American Geophysical Union||en|
|dc.rights||©2013. American Geophysical Union. All Rights Reserved.||en|
|dc.title||The propagation of compaction bands in porous rocks based on breakage mechanics||en|
|pubs.library.collection||Civil and Environmental Engineering publications||en|
|Appears in Collections:||Civil and Environmental Engineering publications|
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