Br treated graphite nanoplatelets for improved electrical conductivity of polymer composites

Li, Jing; Vaisman, Linda; Marom, G.; Kim, Jang Kyo

doi:10.1016/j.carbon.2006.11.031

Cited by 159 publications

(102 citation statements)

References 11 publications

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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]. When nanoparticles are dispersed in an epoxy resin, they have a tendency to re-agglomerate and create only weak bonds with the epoxy molecules by Van der Waals interaction.…”

Section: Fabrication Challengesmentioning

confidence: 99%

“…Despite the inert surface of graphene, Sharma et al [47] showed that some chemical groups can be reactive to it. The effect of bromine functionalised GNP on the mechanical and electrical properties of composites was also studied [22]. The presence of bromine caused the formation of ionic and covalent bonds with the matrix, improving the flexibility of the composites, and the electrical conductivity.…”

Section: Functionalisationmentioning

confidence: 99%

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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%

Section: Functionalisationmentioning

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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“…It has been used recently to build various nanocomposites which exhibit enhanced electronic and adsorption properties. [5][6][7][8][9][10] The graphene layers of GO are stacked together with an interlayer distance varying from 6-12 Å depending on the level of hydration. [11] Oxidation of graphite causes introduction of epoxy and hydroxyl groups to the graphene layers, as well as carboxylic groups mainly located on the edges of the layers.…”

Section: Introductionmentioning

confidence: 99%

MOF–Graphite Oxide Composites: Combining the Uniqueness of Graphene Layers and Metal–Organic Frameworks

2009

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Graphite oxide (GO) / metal-organic framework (MOF-5) nanocomposites are synthesized with various ratios of the two components. In developing the concept of these new adsorbents, it was expected that distorted graphene sheets would contribute to the enhancement in the dispersive interactions, whereas MOF-5 component would contribute to the expansion of the pore space where adsorbates could be stored. Moreover, taking into account the variety of transition and noble metals, which can be used to form the MOF structure, those materials Moreover, specific combination and synergy between GO and MOF-5 units also result in the formation of a unique porosity characteristic of the nanocomposites.3

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“…(Additional evidence for the decrease in nitrile group concentration and their partial polymerization to form a conjugated imine system was received by FTIR analysis [6].) Doping of PAN with Br was monitored by recording the weight increase and by X-ray photoelectron spectroscopy (XPS) analysis of the proportion of ionic/covalent Br as a function of exposure time, as done in our previous study of Br treated graphite nanoplatelets [10]. However, because at this stage we were unable to identify consistent trends, only the results of 8 and 10% Br weight increase, respectively, are reported.…”

Section: Resultsmentioning

confidence: 99%

Dynamic dielectric properties and the γ transition of bromine doped polyacrylonitrile

Cohen¹,

Greenbaum²,

Feldman³

et al. 2007

Express Polym. Lett.

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Abstract. Based on monitoring the γ process (the lowest temperature-relaxation) in polyacrylonitrile (PAN) by dynamic dielectric spectroscopy, new evidence for the formation of a charge transfer complex between bromine dopants and nitrile groups is presented. The experimental work is carried out on PAN and nitrile polymerized PAN with and without bromine doping and the effects of these factors on the γ process are measured. Nitrile polymerization results in diminishing of the γ process and in a 15% increase in its activation energy, whereas bromine doping produces splitting of the original γ process in PAN -coupled with a significant activation energy increase -and its complete disappearance in nitrile polymerized PAN. Both the splitting of the γ process and the higher activation energy reflect bromine-nitrile adduct formation.

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Br treated graphite nanoplatelets for improved electrical conductivity of polymer composites

Cited by 159 publications

References 11 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

MOF–Graphite Oxide Composites: Combining the Uniqueness of Graphene Layers and Metal–Organic Frameworks

Dynamic dielectric properties and the γ transition of bromine doped polyacrylonitrile

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