Multiscale modeling of bone fracture using cohesive finite elements
Bone is a hierarc hical material that exhibit fracture mechanisms at multiple scales and will benefit from amultiscale eval uation approach for better fracture risk assessment. This study developed acohesive finiteelement modeling approach that simulated bone fracture at micro- and macroscale. Simu...
Main Authors: | , |
---|---|
Format: | |
Language: | English |
Online Access: | http://ezproxy.villanova.edu/login?url=https://digital.library.villanova.edu/Item/vudl:454716 |
id |
vudl:454716 |
---|---|
record_format |
vudl |
institution |
Villanova University |
collection |
Digital Library |
modeltype_str_mv |
vudl-system:CollectionModel vudl-system:CoreModel vudl-system:ResourceCollection |
datastream_str_mv |
MEMBER-LIST-RAW LICENSE PARENT-QUERY PARENT-LIST DC AUDIT PARENT-LIST-RAW RELS-EXT MEMBER-QUERY |
hierarchytype |
|
hierarchy_all_parents_str_mv |
vudl:454715 vudl:172968 vudl:641262 vudl:3 vudl:1 |
hierarchy_top_id |
vudl:641262 |
hierarchy_top_title |
Villanova Faculty Publications |
fedora_parent_id_str_mv |
vudl:454715 |
hierarchy_first_parent_id_str |
vudl:454716 |
hierarchy_parent_id |
vudl:454715 |
hierarchy_parent_title |
Ural, Ani |
hierarchy_sequence_sort_str |
0000000000 |
hierarchy_sequence |
0000000000 |
spelling |
Multiscale modeling of bone fracture using cohesive finite elements Ural, Ani Mischinski, Susan <div> <table style="width: 2043px;" border="0" cellspacing="0" cellpadding="0"><tbody><tr><td colspan="1" rowspan="1" width="2043" height="21">Bone is a hierarc hical material that exhibit fracture mechanisms at multiple scales and will benefit from amultiscale eval uation approach for better fracture risk assessment. This study developed acohesive finiteelement modeling approach that simulated bone fracture at micro- and macroscale. Simulation results showed that the microscale fracture toughen- ing was most effective when the cement line had lower strength than the surrounding bone reducing the propensity to fracture at the macroscale. These results demonstrate the importance of cement line strength in controlling the fracture toughening mechanisms and the effect of microscale properties in the whole bone fracture risk assessment.</td></tr></tbody></table> </div> May 2013 Villanova Faculty Authorship vudl:454716 Engineering Fracture Mechanics 103(1), May 2013, 141-152 en |
dc.title_txt_mv |
Multiscale modeling of bone fracture using cohesive finite elements |
dc.creator_txt_mv |
Ural, Ani Mischinski, Susan |
dc.description_txt_mv |
<div>
<table style="width: 2043px;" border="0" cellspacing="0" cellpadding="0"><tbody><tr><td colspan="1" rowspan="1" width="2043" height="21">Bone is a hierarc hical material that exhibit fracture mechanisms at multiple scales and will benefit from amultiscale eval uation approach for better fracture risk assessment. This study developed acohesive finiteelement modeling approach that simulated bone fracture at micro- and macroscale. Simulation results showed that the microscale fracture toughen- ing was most effective when the cement line had lower strength than the surrounding bone reducing the propensity to fracture at the macroscale. These results demonstrate the importance of cement line strength in controlling the fracture toughening mechanisms and the effect of microscale properties in the whole bone fracture risk assessment.</td></tr></tbody></table>
</div> |
dc.date_txt_mv |
May 2013 |
dc.format_txt_mv |
Villanova Faculty Authorship |
dc.identifier_txt_mv |
vudl:454716 |
dc.source_txt_mv |
Engineering Fracture Mechanics 103(1), May 2013, 141-152 |
dc.language_txt_mv |
en |
author |
Ural, Ani Mischinski, Susan |
spellingShingle |
Ural, Ani Mischinski, Susan Multiscale modeling of bone fracture using cohesive finite elements |
author_facet |
Ural, Ani Mischinski, Susan |
dc_source_str_mv |
Engineering Fracture Mechanics 103(1), May 2013, 141-152 |
format |
Villanova Faculty Authorship |
author_sort |
Ural, Ani |
dc_date_str |
May 2013 |
dc_title_str |
Multiscale modeling of bone fracture using cohesive finite elements |
description |
<div>
<table style="width: 2043px;" border="0" cellspacing="0" cellpadding="0"><tbody><tr><td colspan="1" rowspan="1" width="2043" height="21">Bone is a hierarc hical material that exhibit fracture mechanisms at multiple scales and will benefit from amultiscale eval uation approach for better fracture risk assessment. This study developed acohesive finiteelement modeling approach that simulated bone fracture at micro- and macroscale. Simulation results showed that the microscale fracture toughen- ing was most effective when the cement line had lower strength than the surrounding bone reducing the propensity to fracture at the macroscale. These results demonstrate the importance of cement line strength in controlling the fracture toughening mechanisms and the effect of microscale properties in the whole bone fracture risk assessment.</td></tr></tbody></table>
</div> |
title |
Multiscale modeling of bone fracture using cohesive finite elements |
title_full |
Multiscale modeling of bone fracture using cohesive finite elements |
title_fullStr |
Multiscale modeling of bone fracture using cohesive finite elements |
title_full_unstemmed |
Multiscale modeling of bone fracture using cohesive finite elements |
title_short |
Multiscale modeling of bone fracture using cohesive finite elements |
title_sort |
multiscale modeling of bone fracture using cohesive finite elements |
language |
English |
collection_title_sort_str |
multiscale modeling of bone fracture using cohesive finite elements |
fgs.type_txt_mv |
http://fedora.info/definitions/v4/repository#Resource http://www.w3.org/ns/ldp#BasicContainer http://www.w3.org/ns/ldp#Container http://www.w3.org/ns/ldp#RDFSource http://www.w3.org/ns/ldp#Resource http://fedora.info/definitions/v4/repository#Container |
fgs.lastModifiedBy_txt_mv |
fedoraAdmin |
relsext.hasModel_txt_mv |
http://hades.library.villanova.edu:8080/rest/vudl-system:CollectionModel http://hades.library.villanova.edu:8080/rest/vudl-system:CoreModel http://hades.library.villanova.edu:8080/rest/vudl-system:ResourceCollection |
fgs.ownerId_txt_mv |
diglibEditor |
fgs.label_txt_mv |
Multiscale modeling of bone fracture using cohesive finite elements |
fgs.lastModifiedDate_txt_mv |
2021-04-12T19:10:11.945Z |
relsext.isMemberOf_txt_mv |
http://hades.library.villanova.edu:8080/rest/vudl:454715 |
fgs.state_txt_mv |
Active |
fgs.createdDate_txt_mv |
2016-03-29T01:14:45.549Z |
relsext.sortOn_txt_mv |
title |
fgs.createdBy_txt_mv |
fedoraAdmin |
has_order_str |
no |
license.mdRef_str |
http://digital.library.villanova.edu/copyright.html |
license_str |
protected |
has_thumbnail_str |
false |
first_indexed |
2016-03-29T01:14:46Z |
last_indexed |
2021-04-12T19:39:03Z |
_version_ |
1785894176329564161 |
subpages |