Predictive combining multiple variously hybridized low-dimensional nanocarbons in a single additive for nano-sized energetic materials performance enhancement

Abstract We propose to uncover new opportunities for predictive nano-sized energetic materials performance enhancement through manipulating by vibrational interactions, energy exchange as well heat transfer within the reaction zones at nanoscale. The combination of multiple carbon nanostructured with various hybridizations a single substance can unique properties. Due recent fundamental discovery collective atomic vibrations, called phonon waves, manifested in transition domains multilayer nanostructures, incorporation self-organized arrays metastable nanostructures are capable controlling interactions and For using this phenomenon, we into material composition carbon-based allotropes, used catalytic nano-additives, combined assembling them differently hybridized low-dimensional nanocarbon promoters. combining nanocarbons use energy-driven initiation allotropic phase transformations promoters concurrent electron ion irradiation. fine tuning nanoarchitecture functionality mentioned set techniques: irradiation, surface acoustic waves heteroatom doping along application external electromagnetic fields data-driven nanoscale manufacturing approach.