Energetic materials are central to propulsion and detonation technologies, yet their performance is often limited by poor control over energy release across multiple length and time scales. Integrating highly reactive composites with molecular explosives while maintaining structural precision remains challenging. Here we show a three dimensional printing strategy that enables programmable energetic composites by combining highly reactive metastable composite systems with a crystalline high explosive through acoustic-assisted assembly. Uniform coating and intimate interfacial contact produce dense architectures with enhanced thermal reactivity, accelerated pressurisation and increased energy output under confined conditions. Printed filamentary and core-shell structures further enable multistage and geometry-dependent energy release, including sustained combustion, secondary pressurisation and intense fireball formation. Laser-driven and combustion experiments reveal that the energy release characteristics can be systematically tuned by composition and architecture. This work establishes a general route to structure-performance control in energetic materials and highlights additive manufacturing as a powerful platform for designing next-generation reactive and explosive systems.
Chen et al. (Fri,) studied this question.