University of Wollongong
Browse

Size Effects on the Mechanical Properties of Nanoporous Graphene Networks

Download (1.52 MB)
journal contribution
posted on 2024-11-15, 15:15 authored by Dai-Ming Tang, Cui Ren, Ling Zhang, Ying Tao, Peng Zhang, Wei Lv, Xiang Jia, Xiaojuan Jiang, Guangmin Zhou, Takahito Ohmura, Ping Huai, Feng Li, Yoshio BandoYoshio Bando, Dmitri Golberg, Quan-Hong Yang
It is essential to understand the size scaling effects on the mechanical properties of graphene networks to realize the potential mechanical applications of graphene assemblies. Here, a "highly dense-yet-nanoporous graphene monolith (HPGM)" is used as a model material of graphene networks to investigate the dependence of mechanical properties on the intrinsic interplanar interactions and the extrinsic specimen size effects. The interactions between graphene sheets could be enhanced by heat treatment and the plastic HPGM is transformed into a highly elastic network. A strong size effect is revealed by in situ compression of micro- and nanopillars inside electron microscopes. Both the modulus and strength are drastically increased as the specimen size reduces to ≈100 nm, because of the reduced weak links in a small volume. Molecular dynamics simulations reveal the deformation mechanism involving slip-stick sliding, bending, buckling of graphene sheets, collapsing, and densification of graphene cells. In addition, a size-dependent brittle-to-ductile transition of the HPGM nanopillars is discovered and understood by the competition between volumetric deformation energy and critical dilation energy.

History

Citation

Tang, D., Ren, C., Zhang, L., Tao, Y., Zhang, P., Lv, W., Jia, X., Jiang, X., Zhou, G., Ohmura, T., Huai, P., Li, F., Bando, Y., Golberg, D. & Yang, Q. (2019). Size Effects on the Mechanical Properties of Nanoporous Graphene Networks. Advanced Functional Materials, 29 (19), 1900311-1-1900311-10.

Journal title

Advanced Functional Materials

Volume

29

Issue

19

Language

English

RIS ID

134239

Usage metrics

    Categories

    Keywords

    Exports

    RefWorks
    BibTeX
    Ref. manager
    Endnote
    DataCite
    NLM
    DC