Bone-like crack resistance in hierarchical metastable nanolaminate steels

Bone-like crack resistance in hierarchical metastable nanolaminate steels

Fatigue failures create enormous risks for all engineered structures, as well as for human lives, motivating large safety factors in design and, thus, inefficient use of resources. Inspired by the excellent fracture toughness of bone, we explored the fatigue resistance in metastability-assisted mult...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2017-03, Vol.355 (6329), p.1055-1057
Hauptverfasser: Koyama, Motomichi, Zhang, Zhao, Wang, Meimei, Ponge, Dirk, Raabe, Dierk, Tsuzaki, Kaneaki, Noguchi, Hiroshi, Tasan, Cemal Cem
Format: Artikel
Sprache:eng
Schlagworte:
Alloy development
Alloys
Bones
Crack propagation
Design factors
Fatigue
Fatigue cracks
Fatigue failure
Fatigue strength
Ferrous alloys
Fracture mechanics
Fracture toughness
Interface stability
Mechanical analysis
Mechanical properties
Metal fatigue
Microstructure
Phase stability
Safety engineering
Safety factors
Steel
Strategy
Structural steels
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Zusammenfassung:Fatigue failures create enormous risks for all engineered structures, as well as for human lives, motivating large safety factors in design and, thus, inefficient use of resources. Inspired by the excellent fracture toughness of bone, we explored the fatigue resistance in metastability-assisted multiphase steels. We show here that when steel microstructures are hierarchical and laminated, similar to the substructure of bone, superior crack resistance can be realized. Our results reveal that tuning the interface structure, distribution, and phase stability to simultaneously activate multiple micromechanisms that resist crack propagation is key for the observed leap in mechanical response. The exceptional properties enabled by this strategy provide guidance for all fatigue-resistant alloy design efforts.
ISSN:0036-8075
1095-9203
DOI:10.1126/science.aal2766