Simultaneous reduction and surface functionalization of graphene oxide with POSS for reducing fire hazards in epoxy composites

Wang, Xin; Song, Lei; Yang, Hongyu; Xing, Weiyi; Kandola, Baljinder K.; Hu, Yuan

doi:10.1039/c2jm35479a

Cited by 237 publications

(131 citation statements)

References 30 publications

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“…The continuous and compact char surfaces are good barriers to protect the underlying polymers and inhibit the exchange of degradation products, combustible gases and oxygen. 48,49 The results of flammability exhibit that CeMnO2-GNS-EP nanocomposite show the best flame retardancy among EP nanocomposites. By combining TGA and cone calorimetry results, it is reasonably believed that some epoxy chains participated in the carbonization process due to the barrier effect of GNS and the catalysis of Ce-MnO2, and more and better chars are formed, which decrease the flammability of EP nanocomposites.…”

Section: Resultsmentioning

confidence: 99%

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Fabrication of Ce-doped MnO₂decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

et al. 2014

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Ce-doped MnO2-graphene hybrid sheets were fabricated by utilizing an electrostatic interaction between Ce-doped MnO2 and graphene sheets. The hybrid material was analyzed by a series of characterization methods. Subsequently, the Ce-doped MnO2-graphene hybrid sheet was introduced into an epoxy resin, and the fire hazard behaviors of the epoxy nanocomposite were investigated. The results from thermogravimetric analysis exhibited that the incorporation of 2.0 wt% of Ce-doped MnO2-graphene sheets clearly improved the thermal stability and char residue of the epoxy matrix. In addition, the addition of Ce-MnO2-graphene hybrid sheets imparted excellent flame retardant properties to an epoxy matrix, as shown by the dramatically reduced peak heat release rate and total heat release value obtained from a cone calorimeter. The results of thermogravimetric analysis/infrared spectrometry, cone calorimetry and steady state tube furnace tests showed that the amount of organic volatiles and toxic CO from epoxy decomposition were significantly suppressed after incorporating Ce-MnO2-graphene sheets, implying that this hybrid material has reduced fire hazards. A plausible flame-retardant mechanism was hypothesized on the basis of the characterization of char residues and direct pyrolysis-mass spectrometry analysis: during the combustion, Ce-MnO2, as a solid acid, results in the formation of pyrolysis products with lower carbon numbers. Graphene sheets play the role of a physical barrier that can absorb the degraded products, thereby extend their contact time with the metal oxides catalyst, and then promote their propagate on the graphene sheets; meanwhile pyrolysis fragments with lower carbon numbers can be easily catalyzed in the presence of Ce-MnO2. The notable reduction in the fire hazards was mainly attributed to the synergistic action between the physical barrier effect of graphene and the catalytic effect of Ce-MnO2.

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Section: Resultsmentioning

confidence: 99%

“…The dense char layer can lower the efficiency of heat and volatiles transference because of the strong hindering effect, and can provide better flame shielding for the underlying material during combustion. 48,49 The char residue of Ce-MnO2-GNS-EP was also characterized by its XRD pattern, as shown in Fig. 12E.…”

Section: Flame Retardant Mechanismmentioning

confidence: 99%

Fabrication of Ce-doped MnO₂decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

et al. 2014

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“…Small organic molecules, such as organosilicon compounds [64][65][66][67][68], cetyltrimethyl ammonium bromide [69] and pentaerythritol [70], are modified or adsorbed onto the planes and edges of graphene sheets to create organic-small molecule graphene composites. The incorporated small organic molecules act as a bridge between graphene and polymer matrices and form a network structure, thereby increasing the dispersion of graphene and improving the mechanical properties of the composites.…”

Section: Molecules-modified Graphene Composite Flame Retardantsmentioning

confidence: 99%

Graphene-based flame retardants: a review

Sang

et al. 2016

J Mater Sci

184

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Graphene and its derivatives are potential flame retardant materials with good flame retardant performance; in particular, graphene as an adjuvant in combination with inorganic nanomaterials may be a promising candidate of flame retardant. This review describes the flame retardant mechanism, the development trend, and the classification of graphene-based flame retardants. It points out that graphene has attracted intensive interests in the fields of electronics, energy, and information, due to its excellent properties such as high thermal conductivity, good electron transport ability, and large specific surface area. In the meantime, graphene can change the pyrolysis as well as the thermal conductivity, heat absorption, viscosity and dripping of polymer during the combustion process. In other words, graphene can improve the thermal stability of polymer and delay its ignition, and it can also inhibit fire from spreading and reduce heat release rate.

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“…The DTG curve showed a minimum (20.10%/ C) at 141 C, probably as a consequence of the NH 4 FePO 4 ÁH 2 O nanoplate thermal decomposition. 27 The results indicate the process of the loss of water and ammonia.…”

Section: Thermal Propertiesmentioning

confidence: 94%

Flame retardancy and mechanical properties of ferrum ammonium phosphate–halloysite/epoxy polymer nanocomposites

Dong

Lisco

et al. 2014

J of Applied Polymer Sci

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To recycle the nitrogen (N) and phosphorus (P) from wastewater, ferrum ammonium phosphate (FAP)-halloysite nanotubes (HNTs) were synthesized with simulated wastewater containing N, P, and Fe pollutants as raw materials. The adsorption-chemical precipitation in situ method was used to synthesize the target products, and the optimal conditions for the synthesis of the FAPHNTs were obtained. Fourier transform Infrared (FTIR) spectroscopy, energy-dispersive spectroscopy (EDS), scanning electron microscopy, transmission electron microscopy, and thermogravimetric analysis were conducted to characterize the samples. The FAP particle size was 20-30 nm in the FAP-HNTs. The FTIR spectra demonstrated that a small amount of water in the FAP-HNTs promoted the curing reaction. The FAP-HNTs and Exolit OP 1230 (OP) were introduced into epoxy (EP) to prepare the polymer nanocomposites. The heat release rate (HRR) and flammability of the EP composites were tested by microscale combustion calorimetry and UL-94 instruments. The mechanical properties of the EP composites also were tested by a tension testing system. The results indicate that the flame retardancy and mechanical properties of the EP composites were improved by FAP-HNT. The addition of FAP-HNT and OP gave rise to an evident reduction of HRR and a prolonged burning time for the EP. EP/FAP-HNT/OP (20) (where 20 is the loading weight percentage) passed the UL 94 V-0 rating. The analysis of the char revealed the synergy of the FAP-HNTs and OP in reducing the flammability of the polymers. We concluded that these polymers show potential for applications in wastewater treatment and N/P recycling.

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Simultaneous reduction and surface functionalization of graphene oxide with POSS for reducing fire hazards in epoxy composites

Cited by 237 publications

References 30 publications

Fabrication of Ce-doped MnO₂decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

Fabrication of Ce-doped MnO₂decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

Graphene-based flame retardants: a review

Flame retardancy and mechanical properties of ferrum ammonium phosphate–halloysite/epoxy polymer nanocomposites

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Simultaneous reduction and surface functionalization of graphene oxide with POSS for reducing fire hazards in epoxy composites

Cited by 237 publications

References 30 publications

Fabrication of Ce-doped MnO2decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

Fabrication of Ce-doped MnO2decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

Graphene-based flame retardants: a review

Flame retardancy and mechanical properties of ferrum ammonium phosphate–halloysite/epoxy polymer nanocomposites

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Product

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Fabrication of Ce-doped MnO₂decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism

Fabrication of Ce-doped MnO₂decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism