Enhanced fracture toughness in architected interpenetrating phase composites by 3D printing

Enhanced fracture toughness in architected interpenetrating phase composites by 3D printing

Interpenetrating phase composite (IPC), also known as co-continuous composite, is one type of material that may exhibit an unusual combination of high stiffness, strength, energy absorption, and damage tolerance. Here we experimentally demonstrate that IPCs fabricated by 3D printing technique with r...

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Bibliographic Details
Published in:Composites science and technology Vol. 167; pp. 251 - 259
Main Authors: Li, Tiantian, Chen, Yanyu, Wang, Lifeng
Format: Journal Article
Language:English
Published: Barking Elsevier Ltd 20-10-2018
Elsevier BV
Subjects:
3-D printers
3D printing
Architected materials
Crack bridging
Damage tolerance
Energy absorption
Fracture toughness
Interpenetrating phase composites
Mechanical properties
Multifunctional
State of the art
Stiffness
Three dimensional composites
Three dimensional printing
Interpenetrating phase composites
Architected materials
Multifunctional
3D printing
Fracture toughness
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Summary:Interpenetrating phase composite (IPC), also known as co-continuous composite, is one type of material that may exhibit an unusual combination of high stiffness, strength, energy absorption, and damage tolerance. Here we experimentally demonstrate that IPCs fabricated by 3D printing technique with rationally designed architectures can exhibit a fracture toughness 16 times higher than that of conventionally structured composites. The toughening mechanisms arise from the crack-bridging, process zone formation and crack-deflection, which are intrinsically controlled by the rationally designed interpenetrating architectures. We further show that the prominently enhanced fracture toughness in the architected IPCs can be tuned by tailoring the stiffness contrasts between the two compositions. The findings presented here not only quantify the fracture behavior of complex architected IPCs but also demonstrate the potential to achieve tailorable mechanical properties through the integrative rational design and the state-of-the-art advanced manufacturing technique.
ISSN:0266-3538
1879-1050
DOI:10.1016/j.compscitech.2018.08.009