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Issue 44, 2017
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Asynchronous cracking with dissimilar paths in multilayer graphene

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Abstract

Multilayer graphene consists of a stack of single-atomic-thick monolayer graphene sheets bound with π–π interactions and is a fascinating model material opening up a new field of fracture mechanics. In this study, fracture behavior of single-crystalline multilayer graphene was investigated using an in situ mode I fracture test under a scanning electron microscope, and abnormal crack propagation in multilayer graphene was identified for the first time. The fracture toughness of graphene was determined from the measured load–displacement curves and the realistic finite element modelling of specimen geometries. Nonlinear fracture behavior of the multilayer graphene is discussed based on nonlinear elastic fracture mechanics. In situ scanning electron microscope images obtained during the fracture test showed asynchronous crack propagation along independent paths, causing interlayer shear stress and slippages. We also found that energy dissipation by interlayer slippages between the graphene layers is the reason for the enhanced fracture toughness of multilayer graphene. The asynchronous cracking with independent paths is a unique cracking and toughening mechanism for single-crystalline multilayer graphene, which is not observed for the monolayer graphene. This could provide a useful insight for the design and development of graphene-based composite materials for structural applications.

Graphical abstract: Asynchronous cracking with dissimilar paths in multilayer graphene

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Publication details

The article was received on 20 Jun 2017, accepted on 07 Oct 2017 and first published on 10 Oct 2017


Article type: Paper
DOI: 10.1039/C7NR04443G
Citation: Nanoscale, 2017,9, 17325-17333
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    Asynchronous cracking with dissimilar paths in multilayer graphene

    B. Jang, B. Kim, J. Kim, H. Lee, T. Sumigawa and T. Kitamura, Nanoscale, 2017, 9, 17325
    DOI: 10.1039/C7NR04443G

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