Failure Processes in Embedded Monolayer Graphene under Axial Compression

Androulidakis, Charalampos; Koukaras, Emmanuel Ν.; Frank, Otakar; Tsoukleri, Georgia; Sfyris, D.; Parthenios, John; Pugno, Nicola; Papagelis, Konstantinos; Новоселов, К. С.; Galiotis, Costas

doi:10.1038/srep05271

Cited by 69 publications

(117 citation statements)

References 43 publications

(58 reference statements)

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“…k; l are the Lame constants of the substrate. We disregard viscous effects, since we have in mind experiments with slow rate such as the one's performed in Androulidakis et al (2014). e 0 b denotes the internal strain field the substrate has.…”

Section: Mathematical Prerequisitesmentioning

confidence: 99%

“…For the substrate we make three different assumptions corresponding to three common materials used as substrate: Polyethylene terephthalate (PET), Polymethyl methacrylate (PMMA) and Polydimethylsiloxane (PDMS). In the mathematical model these are introduced through their Lame constants, k; l. Being aware that these polymeric substrate's behave in a viscoelastic manner, we assume the viscous response to be negligible, since we have in mind experiments with slow rate such as those in Androulidakis et al (2014).…”

Section: Introductionmentioning

confidence: 99%

“…Then the technique of Raman spectroscopy can be applied to measure the mechanical properties of graphene by measuring the G and 2D peak of the Raman spectra. In Androulidakis et al (2014) we embed a graphene flake on a substrate and apply a tensional loading to the system graphene/substrate using either the technique of cantilever beam or the four point bending technique.…”

Section: Introductionmentioning

confidence: 99%

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Graphene resting on substrate: Closed form solutions for the perfect bonding and the delamination case

Sfyris

Androulidakis

Galiotis

2015

International Journal of Solids and Structures

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a b s t r a c tWe study closed form solutions for the perfect bonding and the delamination case for a monolayer graphene sheet resting on an elastic foundation. The theoretical framework we adopt is restricted to the materially and geometrically linear case. Graphene is modeled as a hexagonal 2-lattice, while the substrate is assumed to behave in an isotropic linearly elastic manner. Initially, we ignore out-of-surface motions and study the case of biaxial tension/compression and simple shear. We find the components of the shift vector by solving the equations ruling the shift vector. We then substitute this expression for the shift vector components to the momentum equation. This way we obtain conditions that the field of the internal strains, the strain constants and the material parameters should satisfy in order biaxial tension/compression and simple shear to be solutions for all equilibrium equations. For the particular case of axial strain and for the simple shear case we plot the mean stress components versus strain for three different substrates. Then, we take into account out-of-surface motions. We assume the out-of-surface displacement to be the product of a wave-like function and an unknown function, which we determine under certain conditions. These conditions are constraints that the field of the internal strains, the strain constant and the material characteristics of the substrate and graphene should satisfy in order the equilibrium equations to be satisfied. These cases pertain to the perfect bonding case. Distinguishing film's displacement from the bulk (substrate) displacement we study the case where delamination occur. We again use a semi-inverse method: we assume film's displacement to be the product of a wave-like function with an unknown function. The bulk's displacement is assumed to be different from the one of the film, in areas of delamination. We determine the unknown function present in the displacement of the film, by requiring the momentum equations to be satisfied.

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Section: Mathematical Prerequisitesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Graphene resting on substrate: Closed form solutions for the perfect bonding and the delamination case

Sfyris

Androulidakis

Galiotis

2015

International Journal of Solids and Structures

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“…l c is larger in case of poor stress transfer (i.e., low interaction) between the sheet and the matrix. [15,16] The strain within single graphene sheets [17][18][19] or even in composites [20] can be measured and mapped using Raman microscopy; for multilayer graphene ≈10 times larger than the one of macroscopic steel sheets (Figure 1c). [13] The mechanical behavior of graphene and graphene oxide (GO) at the nanoscale has been also intensively studied using atomistic modeling [10] (Figure 1d,e), or correlating mechanical properties with structure and geometry of chemical bonds at atomic scale (Figure 1f,g), [7,14] as described in more detail in following sections.…”

Section: Strong But Flexiblementioning

confidence: 99%

“…[5,19,48] 3) Chemistry -a fine control of the surface chemistry of the nanosheets will be required to tune the density and nature of chemical defects, to maximize the interaction between the sheets and the polymer matrix and hence ensure uniform dispersion in the composite and efficient stress transfer between the different phases of the composite material with moderate intrinsic flake strength reduction.…”

Section: Processing Of Graphene Sheets In Compositesmentioning

confidence: 99%

Nanoscale Mechanics of Graphene and Graphene Oxide in Composites: A Scientific and Technological Perspective

Palermo

Kinloch

Ligi³

et al. 2016

Advanced Materials

142

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Graphene shows considerable promise in structural composite applications thanks to its unique combination of high tensile strength, Young's modulus and structural flexibility which arise due to its maximal chemical bond strength and minimal atomic thickness. However, the ultimate performance of graphene composites will depend, in addition to the properties of the matrix and interface, on the morphology of the graphene used, including the size and shape of the sheets and the number of chemical defects present. For example, whilst oxidized sp(3) carbon atoms and vacancies in a graphene sheet can degrade its mechanical strength, they can also increase its interaction with other materials such as the polymer matrix of a composite, thus maximizing stress transfer and leading to more efficient mechanical reinforcement. Herein, we present an overview of some recently published work on graphene mechanical properties and discuss a list of challenges that need to be overcome (notwithstanding the strong hype existing on this material) for the development of graphene-based materials into a successful technology.

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