Connectivity percolation of polydisperse anisotropic nanofillers

Otten, Rhj Ronald; Schoot, Ppam Paul van der

doi:10.1063/1.3559004

Cited by 127 publications

(185 citation statements)

References 54 publications

(130 reference statements)

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“…Using simulation in physics allows the number of experiments to be reduced and thus time and cost for development at laboratory and industry scale by linking theory and experimentation [10][11][12][13][14][15][16]. Functionalisation of nanoparticles, when they are dispersed in an epoxy resin, could have two aims: improving the dispersion quality by decreasing the interaction between nanoparticles [17][18][19], and improving the mechanical properties of the composite by improving the interfacial bonding between matrix, nanoparticles and micro-reinforcement [20][21][22][23].…”

Section: Fabrication Challengesmentioning

confidence: 99%

Effect of pre and Post-Dispersion on Electro-Thermo-Mechanical Properties of a Graphene Enhanced Epoxy

Poutrel

Wang

et al. 2016

Appl Compos Mater

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Graphene nanoplatelet (GNP) modified epoxy nanocomposites are becoming attractive to aerospace due to possible improvements in their mechanical, electrical and thermal properties at no weight cost. The process of obtaining reliable material systems provides many challenges, especially at larger scale (a volume effect). This paper reports on the main fabrication stages of GNP-based epoxy composites, namely (i) pre-dispersion, (ii) dispersion, and (iii) post-dispersion. Each stage is developed to show the interest and potential it delivers for property enhancement. Chemical modification of GNP is presented; functionalisation by Triton X-100 shows elastic modulus improvements of the epoxy at low particle content (≤3%). The post-dispersion step as an alignment of GNP into the epoxy by an electrical field is discussed. The electrical conductivity is below the simulated percolation threshold and an improvement of the thermal diffusivity of 220% when compared to non-oriented GNP epoxy sample is achieved. The work demonstrates how the addition of functionalised graphene platelets to an epoxy resin will allow it to act as electrical and thermal conductor rather than as insulator

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Section: Fabrication Challengesmentioning

confidence: 99%

Effect of pre and Post-Dispersion on Electro-Thermo-Mechanical Properties of a Graphene Enhanced Epoxy

Poutrel

Wang

et al. 2016

Appl Compos Mater

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“…Later, Ambrosetti et al [17] conducted a numerical study to investigate a system's percolative properties consisting of hard oblate ellipsoids of revolution surrounded with soft penetrable shells. Since the previously mentioned computational works were focusing only on material systems with constant filler material and geometrical properties, Otten et al [18] developed an analytical approach to investigate the percolation behaviour of polydisperse nanofillers of platelet-based composites. However, their modelling approach was subject to certain limitations, that is, the platelet thickness and the tunnelling decay length have to be of the same order of magnitude, and the diameter of the disk-like fillers needs to be much larger than the disk thickness.…”

Section: Electrical Simulation Modelsmentioning

confidence: 99%

Predictive Model of Graphene Based Polymer Nanocomposites: Electrical Performance

2016

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In this computational work, a new simulation tool on the graphene/polymer nanocomposites electrical response is developed based on the finite element method (FEM). This approach is built on the multi-scale multi-physics format, consisting of a unit cell and a representative volume element (RVE). The FE methodology is proven to be a reliable and flexible tool on the simulation of the electrical response without inducing the complexity of raw programming codes, while it is able to model any geometry, thus the response of any component. This characteristic is supported by its ability in preliminary stage to predict accurately the percolation threshold of experimental material structures and its sensitivity on the effect of different manufacturing methodologies. Especially, the percolation threshold of two material structures of the same constituents (PVDF/Graphene) prepared with different methods was predicted highlighting the effect of the material preparation on the filler distribution, percolation probability and percolation threshold. The assumption of the random filler distribution was proven to be efficient on modelling material structures obtained by solution methods, while the through-the -thickness normal particle distribution was more appropriate for nanocomposites constructed by film hot-pressing. Moreover, the parametrical analysis examine the effect of each parameter on the variables of the percolation law. These graphs could be used as a preliminary design tool for more effective material system manufacturing.

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“…39 However, our result is consistent with recent theoretical predictions that, for composites of randomly oriented, monodisperse conducting discs in an insulating matrix, the percolation threshold is actually independent of disk diameter. 40 This work suggests f c to scale only with disk thickness, a, as f c ¼ 2a/l(5p + 6), where l is the hopping distance. The independence of disk diameter is due to the effect of volume exclusion.…”

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confidence: 99%

Percolation scaling in composites of exfoliated MoS2 filled with nanotubes and graphene

et al. 2012

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Applications of films of exfoliated layered compounds in many areas will be limited by their relatively low electrical conductivity. To address this, we have prepared and characterised composites of a nano-conductor (nanotubes or graphene) embedded in a matrix of exfoliated MoS 2 nanosheets. Solvent exfoliation of MoS 2 nanosheets, followed by blending with dispersions of graphene or nanotubes allowed the formation of such composite films by vacuum filtration. This gave spatially uniform mixtures with fully tuneable nano-conductor content. By addition of the nano-conducting phase, it was possible to vary the electrical conductivity of the composite over nine orders of magnitude. For both filler types the conductivity followed percolation scaling laws both above and below the percolation threshold. In the case of SWNT-filled composites, conductivities as high as $40 S m À1 were achieved at volume fractions as low as $4%.Inorganic layered compounds are an exciting class of materials which have received renewed attention in recent years. These systems consist of 2-dimensional nanosheets which stack, typically by van der Waals interactions, to form three dimensional crystals. 1 These materials are exciting because they are found in a wide range of types with a broad palate of physical properties. After graphite, probably the most wellknown layered compounds are the family of transition metal dichalcogenides (TMDs). These materials have the chemical composition MX 2 where M is a transition metal (commonly, but not limited to Ti, Nb, Ta, Mo, W) and X is a chalcogen (e.g. S, Se, Te). This family of materials is of interest due to their versatile electronic and electrochemical properties.2,3 Another family of layered compounds are the transition metal oxides, 4 with layered MnO 2 (i.e. d-MnO 2 ) showing potential for applications in supercapacitor electrodes.5 Also well-known are the layered materials; Bi 2 Te 3 , Sb 2 Te 3 , Bi 2 Se 3 and Sb 2 Se 3 , which have great potential as thermoelectric materials.

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Connectivity percolation of polydisperse anisotropic nanofillers

Cited by 127 publications

References 54 publications

Effect of pre and Post-Dispersion on Electro-Thermo-Mechanical Properties of a Graphene Enhanced Epoxy

Effect of pre and Post-Dispersion on Electro-Thermo-Mechanical Properties of a Graphene Enhanced Epoxy

Predictive Model of Graphene Based Polymer Nanocomposites: Electrical Performance

Percolation scaling in composites of exfoliated MoS2 filled with nanotubes and graphene

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