Rapid assembly of multilayer nanostructured FG/Al energetic materials to obtain high combustion reactivity.

The multilayer nanostructured FG/Al (MN-FG/Al) energetic materials with particle mosaic have been rapidly assembled by the intercalation-like method, and the energy output performance of these MN-FG/Al energetic materials can be effectively regulated by changing the ratio of FG and nAl. [Display omitted] • Propose an efficient strategy towards the design of energetic materials. • Multilayer nanostructured have assembled by the intercalation-like method. • Energy output can be effectively regulated by changing the ratio of FG and Al. • Oxygen content determines the reaction and obtains different pressure outputs. Fluorinated reactive materials as new energetic materials are widely studied because of their high combustion heat and the ability to release large amounts of gaseous products. In order to further improve combustion reaction and the energy release efficiency, structural processing strategy is usually adopted to construct unique microstructures for fluorinated reactive materials. In this work, it is found that fluorinated graphene (FG) and nano-aluminum (nAl) can be rapidly assembled by the intercalation-like method to form multilayer nanostructured energetic materials with particle mosaic. Based on this, the energy output performance of these multilayer nanostructured energetic materials can be effectively regulated by changing the ratio of FG to nAl. The shortest laser ignition delay time (8 ms) and the longest burning time (56 ms) can be achieved for the multilayer nanostructured energetic material with proper FG/Al ratio, while the burning rate of the sample spline can reach 14.83 cm/s. In addition, the reaction process of multilayer nanostructured FG/Al energetic materials depends upon oxygen content that participates in the reaction in different atmospheres, leading to the different pressure output performance. This study provides a promising strategy for the further application of fluorinated reactive materials in the field of energetic materials. [ABSTRACT FROM AUTHOR]