Abstract

Surface engineering plays a crucial role in improving the performance of high energy materials, and polydopamine (PDA) is widely used in the field of energetic materials for surface modification and functionalization. In order to obtain high-quality HMX@PDA-based PBX explosives with high sphericity and a narrow particle size distribution, composite microspheres were prepared using co-axial droplet microfluidic technology. The formation mechanism, thermal behavior, mechanical sensitivity, electrostatic spark sensitivity, compressive strength, and combustion performance of the microspheres were investigated. The results show that PDA can effectively enhance the interfacial interaction between the explosive particles and the binder under the synergistic effect of chemical bonds and the physical "mechanical interlocking" structure. Interface reinforcement causes the thermal decomposition temperature of the sample microspheres to move to a higher temperature, with the sensitivity to impact, friction, and electrostatic sparks (for S-1) increasing by 12.5%, 31.3%, and 81.5% respectively, and the compressive strength also increased by 30.7%, effectively enhancing the safety performance of the microspheres. Therefore, this study provides an effective and universal strategy for preparing high-quality functional explosives, and also provides some reference for the safe use of energetic materials in practical applications. Polydopamine (PDA) enables surface modification to enhance the interfacial interaction between explosive adhesion and binder. In order to obtain high-quality HMX@PDA-based PBX explosives, sample microspheres with high sphericity and narrow particle size distribution were prepared by a co-axial droplet microfluidic technology. PDA can improve the interface effect under the synergistic effect of physics and chemistry, and greatly improve the safety performance of PBX microspheres. • Successfully prepared spherical HMX@PDA-based PBX microspheres with concentrated particle size distribution. • Polydopamine strengthens the interfacial action of PBX through chemical and physical interlocking structures. • Enhanced interfacial action improves the safety performance of PBX microspheres. • Enhanced interfacial action facilitates the propagation of combustion waves and the concentrated release of energy.