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The Stabilization Mechanisms of CL-20 Crystals by Intercalation of Graphene Oxide Coated with Polydopamine

Haorui Zhang, Mingjie Wen, Xue-Xue Zhang, Jie-Yao Lyu, Geng Xu, Qingzhao Chu, Dongping Chen, Qi‐Long Yan

2025The Journal of Physical Chemistry B9 citationsDOI

Abstract

Hexaazaisowurtzitane (CL-20) is a high-energy-density compound with poor thermal stability, which hinders its application in composite energetic systems. A bi-interface structure of polydopamine-coated graphene oxide (GO@PDA) is shown to markedly improve thermal stability compared with pristine CL-20 and single-layer coatings. Reactive molecular dynamics simulations enhanced by a neural network potential (NNP) reveal that the delayed onset of decomposition arises from suppressed NO 2 release and altered spatial density distribution, while interfacial −OH and −COOH groups consume intermediates, redirect decomposition pathways, and inhibit autocatalytic chain reactions. This dual-modulation mechanism produces controlled energy release, reduced mechanical sensitivity, and a more gradual decomposition profile. The findings demonstrate the potential of interfacial nanostructures to regulate the thermal response of energetic crystals and suggest a generalizable strategy for enhancing the stability and safety of functional energetic composites.

Topics & Concepts

Intercalation (chemistry)GrapheneMaterials scienceAutocatalysisOxideThermal decompositionThermal stabilityComposite numberDecompositionChemical engineeringMolecular dynamicsNanostructureThermalNanotechnologyDestabilisationActivation energyDensity functional theoryChemical physicsNanoparticleMechanism (biology)Potential energyAdsorptionKineticsStability (learning theory)NucleationChemical decompositionThermal energyEnergetic materialEnergetic Materials and CombustionThermal and Kinetic AnalysisGraphene research and applications