Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
10283691 | Composite Structures | 2012 | 8 Pages |
Abstract
Dynamic and static fracture properties of Graphene Sheets (GSs) and Carbon nanotubes (CNTs) with different sizes are investigated based on an empirical inter-atomic potential function that can simulate nonlinear large deflections of nanostructures. Dynamic fracture of GSs and CNTs are studied based on wave propagation analysis in these nanostructures in a wide range of strain-rates. It is shown that wave propagation velocity is independent from strain-rate while dependent on the nanostructure size and approaches to 2.2Â ÃÂ 104Â m/s for long GSs. Also, fracture strain shows extensive changes versus strain-rate, which has not been reported before. Fracture stress is determined as 115Â GPa for GSs and 122Â GPa for CNTs which are independent from the strain-rate; in contrast to the fracture strain. Moreover, fracture strain drops at extremely high strain-rates for GSs and CNTs. These features are considered as capability of carbon nanostructures for reinforcing nanocomposites especially under impact loadings up to high strain-rates.
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Physical Sciences and Engineering
Engineering
Civil and Structural Engineering
Authors
S.A. Niaki, J.R. Mianroodi, M. Sadeghi, R. Naghdabadi,