The Impact of Metastable Intermolrecular Nanocomposite Particles on Kinetic Decomposition of Heterocyclic Nitramines Using Advanced Solid‐Phase Decomposition Models

Elbasuney, Sherif; Hamed, Abdelaziz; Yehia, M.; Ramzy, Hesham; Abdelgawad, Ahmed; Gobara, Mohamed; Mokhtar, Mohamed

doi:10.1007/s10904-021-02007-z

Cited by 3 publications

(1 citation statement)

References 38 publications

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“…Including ferric oxide nanocatalyst can absorb gas reactive molecules on its surface and boost the reaction rate and decomposition enthalpy [31]. Furthermore, the two exothermic decomposition peaks were shifted to a lower decomposition temperature and also the second decomposition peak started before the end of the first decomposition which confirms the rapid catalytic effect (Fig.…”

Section: Catalytic Decomposition Of Apsupporting

confidence: 52%

Soild-state decomposition mechanisms with conversion extent for ammonium percholorate catalyzed with nanothermite particles

Hamed

Gobara

Mokhtar

et al. 2022

J Therm Anal Calorim

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Colloidal ferric oxide/aluminum nanothermite mixture was incorporated into ammonium percholorate (AP). Nanothermite particles experienced an increase in AP decomposition enthalpy by 120% using DSC. Decomposition kinetic study was performed using integral isoconversional models including Kissinger and KAS models. Nanothermite particles offered decrease in AP activation energy by 55 and 44% using KAS and Kissinger models, respectively. AP nanocomposite is running through three decomposition steps according to extent of conversion: first-order decomposition with Ea = 41.08 kJ.mol−1 (α = 0: 0.25), two-dimensional decomposition with Ea = 71.90 kJ.mol−1 (α = 0.25: 0.6), and one-dimensional diffusion reaction with Ea = 97.10 kJ.mol−1 (α = 0.6:0.9).

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Section: Catalytic Decomposition Of Apsupporting

confidence: 52%

Soild-state decomposition mechanisms with conversion extent for ammonium percholorate catalyzed with nanothermite particles

Hamed

Gobara

Mokhtar

et al. 2022

J Therm Anal Calorim

Self Cite

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Kinetic Study and Thermal Decomposition Mechanisms of Superthermite–Based Nitrocellulose Nanocomposite

Hamed

Gobara

Mokhtar

et al. 2022

Combustion Science and Technology

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Effect of Metastable Intermolecular Composites on the Thermal Decomposition of Glycidyl Azide Polymer Energetic Thermoplastic Elastomer

Sang,

Luo

2024

Polymers

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Glycidyl azide polymer energetic thermoplastic elastomer (GAP-ETPE) has become a research hotspot due to its excellent comprehensive performance. In this paper, metastable intermolecular energetic nanocomposites (MICs) were prepared by a simple and safe method, and the catalytic performance for decomposition of GAP-ETPE was studied. An X-ray diffraction (XRD) analysis showed that the MICs exhibited specific crystal formation, which proved that the MICs were successfully prepared. Morphology, surface area, and pore structure analysis showed that the Al/copper ferrite and Al/Fe2O3 MICs had a large specific surface area mesoporous structure. The Al/CuO MICs did not have a mesoporous structure or a large surface area. The structure of MICs led to their different performance for the GAP-ETPE decomposition catalysis. The increase in specific surface area is a benefit of the catalytic performance. Due to the easier formation of complexes, MICs containing Cu have better catalytic performance for GAP-ETPE decomposition than those containing Fe. The conclusions of this study can provide a basis for the adjustment of the catalytic performance of MICs in GAP-ETPE propellants.

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The Impact of Metastable Intermolrecular Nanocomposite Particles on Kinetic Decomposition of Heterocyclic Nitramines Using Advanced Solid‐Phase Decomposition Models

Cited by 3 publications

References 38 publications

Soild-state decomposition mechanisms with conversion extent for ammonium percholorate catalyzed with nanothermite particles

Soild-state decomposition mechanisms with conversion extent for ammonium percholorate catalyzed with nanothermite particles

Kinetic Study and Thermal Decomposition Mechanisms of Superthermite–Based Nitrocellulose Nanocomposite

Effect of Metastable Intermolecular Composites on the Thermal Decomposition of Glycidyl Azide Polymer Energetic Thermoplastic Elastomer

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