Hybrid FGO to composite energetic materials and its “intelligent” responses to thermal stimulus

Abstract

Abstract Fluorinated graphene (FGO) was a two-dimensional layered compound with thermal conductivity and hydrophobicity, Different percentage of FGO (1.00 wt.%, 3.00 wt.%, 5.00 wt.%) was added to the composite energetic system boron/potassium nitrate (B/KNO3). Through elemental analysis (EA), Fourier transform infrared spectroscopy (FTIR) and X-ray photoelectron spectroscopy (XPS), the results show that with the increase of fluorination degree, the stretching vibration peak of C-F bond was more obvious, and the contents of fluorocarbon functional groups, especially C-F2 rise. The results of synchronous thermal analysis and mass spectrometry (DSC-TG-MS) showed that the initial decomposition temperature of fluorinated graphene was around 400 ℃, the enthalpy value was about 7279 J/g− 1, and a large number of fluorine-containing gas products arising therefrom. The effect of fluorinated graphene on the thermal decomposition performance of energetic system was analyzed by DSC-MS. The results show that fluorinated graphene delayed initial exothermic peak temperature of B/KNO3 system, and promoted subsequent exothermic reaction. The service performances of B/KNO3 composites were compared with or without FGO. While adding fluorinated graphene, the moisture resistance and thermal conductivity of the B/KNO3 composites was improved, flame sensitivity was reduced, thermal safety waas improved, gaseous products and combustion heat were increased, flame duration was prolonged, and the ignition delay period was shortened. It was implied that the present of FGO made the composite energetic materials safer under lower heat and more reliable under high heat. FGO played a role of intelligent regulation and smart responds to different thermal stimuli.