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Indexed by:Journal Papers

First Author:Liu, Jingyu

Correspondence Author:Yan, C (reprint author), QUT, Sci & Engn Fac, Sch Chem Phys & Mech Engn, Brisbane, Qld, Australia.

Co-author:Bai, Ruixiang,Lei, Zhenkun,Xu, Chun,Ye, Qingsong,Martens, Wayde,Yarlagadda, Prasad K. D. V.,Yan, Cheng

Date of Publication:2019-09-29

Journal:COMPOSITES SCIENCE AND TECHNOLOGY

Included Journals:EI、SCIE

Volume:182

ISSN No.:0266-3538

Key Words:Bioinspired composites; Fracture toughness; Interfacial strength; Modelling; Finite element analysis (FEA)

Abstract:Strength and toughness have been generally deemed as two incompatible properties in many materials. However, balanced toughness and strength have been observed in biomaterials, whose hard and soft phases are arranged into unique and hierarchical architectures. Therefore, it is necessary to understand the underpinning toughening mechanisms and develop reliable procedures that can mimic these unique structures at different length scales. Here, alumina-Poly(methyl methacrylate) (PMMA) composites were prepared using freeze casting combined with interface modification (silanization treatment). High failure strain (similar to 4.5%) is achieved in these composites. The overall toughness can be tailored through modifying the interfacial strength between alumina and PMMA. A weaker interface (similar to 8 MPa) leads to a greater toughness (3.1 MPa m(1/2)), which is even greater than the constituent phases, i.e., alumina (2.71 MPa m(1/2)) and PMMA (1.1 MPa m(1/2)). Using a cohesive zone model and extended finite element method (XFEM), the toughening mechanism has been investigated.