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Autori principali: Greff, Christian, Moretti, Paolo, Zaiser, Michael
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2405.18994
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author Greff, Christian
Moretti, Paolo
Zaiser, Michael
author_facet Greff, Christian
Moretti, Paolo
Zaiser, Michael
contents We investigate interface failure of model materials representing architected thin films in contact with heterogeneous substrates. We find that, while systems with statistically isotropic distributions of impurities derive their fracture strength from the ability to develop rough detachment fronts, materials with hierarchical microstructures confine failure near a prescribed surface, where crack growth is arrested and crack surface correlations are suppressed. We develop a theory of network Green's functions for the systems at hand, and we find that the ability of hierarchical microstructures to control failure mode and locations comes at no performance cost in terms of peak stress and specific work of failure and derives from the quenched local anistotropy of the elastic interaction kernel.
format Preprint
id arxiv_https___arxiv_org_abs_2405_18994
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Tuning load redistribution and damage near heterogeneous interfaces
Greff, Christian
Moretti, Paolo
Zaiser, Michael
Materials Science
We investigate interface failure of model materials representing architected thin films in contact with heterogeneous substrates. We find that, while systems with statistically isotropic distributions of impurities derive their fracture strength from the ability to develop rough detachment fronts, materials with hierarchical microstructures confine failure near a prescribed surface, where crack growth is arrested and crack surface correlations are suppressed. We develop a theory of network Green's functions for the systems at hand, and we find that the ability of hierarchical microstructures to control failure mode and locations comes at no performance cost in terms of peak stress and specific work of failure and derives from the quenched local anistotropy of the elastic interaction kernel.
title Tuning load redistribution and damage near heterogeneous interfaces
topic Materials Science
url https://arxiv.org/abs/2405.18994