S. D. Jiang, Z. M. Bai, G. Tang, L. Song, A. A. Stec, T. R. Hull, J. Zhan and Y. Hu (2014) Fabrication of Ce-doped MnO2 decorated graphene sheets for fire safety applications of epoxy composites: flame retardancy, smoke suppression and mechanism. Journal/Journal Of Materials Chemistry A 2 17341-17351. [In English]
Web link: http://dx.doi.org/10.1039/c4ta02882a
Keywords: OCTAHEDRAL MOLECULAR-SIEVES; POLY(BUTYLENE SUCCINATE) COMPOSITES; LAYERED SILICATE NANOCOMPOSITES; EXFOLIATED GRAPHITE OXIDE; FUNCTIONALIZED GRAPHENE; CARBON NANOTUBES; MANGANESE OXIDE; THERMAL-PROPERTIES; FACILE SYNTHESIS; OXIDATION

Abstract: 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.