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Thermal Decomposition Pathways in Perovskite Energetic Material DAP-7: Mechanisms and Metal Oxide Mediation

Ruizhi Pu, Xing-Da Wei, Yu Wang, Nai-Ting Tao, Peng Deng, Shao‐Li Chen, Qi‐Long Yan

2025Langmuir6 citationsDOI

Abstract

Perovskite energetic material [C 6 H 14 N 2 )(NH 3 NH 2 )(ClO 4 ) 3 ] (DAP-7) exhibits an exceptional detonation performance and thermal stability. This study elucidates its thermal decomposition behavior and added metal oxide mediation. Monoclinic DAP-7 crystals underwent a phase transition at 112 °C, followed by a two-stage exothermic decomposition (peak at 383 °C). Kinetic analysis via Kissinger, combined, and Friedman methods yielded activation energies of 238.19 kJ/mol (initial step) and 188.99 kJ/mol (secondary step), governed by A2 mechanisms (random two-dimensional nucleation and nucleus growth model). Gas-phase products (H 2 O, CO, HCl, NH 3, etc.) were identified via synchronous FTIR-MS. Incorporation of Fe 2 O 3 consolidated the decomposition pathway into a single peak (Δ T = −40 °C), reducing energy activation to 193.80 kJ/mol, while CuO accelerated early-stage reactions (peak shift +140 °C) via reactive intermediate enrichment. Combustion tests revealed that DAP-7/CuO achieved a remarkable linear burning rate of 32 mm/s, outperforming pure DAP-7 (7.1 mm/s). Theoretical calculations and experimental validation demonstrate that DAP-7’s hexagonal prism morphology and crystal lattice stability, with dominant H···O/H···H interactions, stabilize the perovskite framework, and added metal oxides strategically modulate decomposition pathways, which are beneficial for enhancing energy release efficiency and combustion dynamics. These findings position DAP-7 as a promising candidate for high-energy propellant applications, with catalytic mediation engineering offering a viable pathway to tailor its reactivity performance.

Topics & Concepts

Perovskite (structure)Thermal decompositionActivation energyMaterials scienceNucleationPropellantOxideMonoclinic crystal systemChemical engineeringExothermic reactionDecompositionReactivity (psychology)MetalEnergetic materialChemistryPhysical chemistryChemical physicsMesoporous materialCombustionChemical decompositionCrystal (programming language)Crystal structureThermodynamicsPhase (matter)NanocrystalCrystallographyInorganic chemistryEnergetic Materials and CombustionRocket and propulsion systems researchCatalytic Processes in Materials Science