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Ignition and Combustion Characteristics of Al/TiB<sub>2</sub>-Based Nanothermites: Effect of Bifuel Distribution

Vidushi Singh, Tao Wu, Ludovic Salvagnac, Alain Estève, Carole Rossi

2024ACS Applied Nano Materials10 citationsDOIOpen Access PDF

Abstract

Aluminum has demonstrated compelling attributes over decades of research, encompassing affordability, abundance, and a high specific energy density when utilized as a fuel in energetic materials such as nanothermites. However, fully realizing the ignition and combustion performance of Al poses a significant challenge, primarily due to its high ignition point and sintering tendency, the latter being hypothesized to be the rate-limiting step in Al-based nanothermite combustion. Herein, we examine the influence of nano-TiB 2 addition on the ignition and combustion properties of CuO/Al by adjusting the Al-TiB 2 binary fuel distribution. Magnetron-sputtered CuO/Al-TiB 2 multilayers were prepared, and their ignition and combustion characteristics were studied. It was found that all configurations of the CuO/Al-TiB 2 system outperform CuO/Al. Notably, 62.5% loading demonstrated the most significant improvement in the ignition delay, with a decrease of ∼100%. Furthermore, each nano-TiB 2 -loaded CuO/Al thermite exceeded the propagation rate of CuO/Al by a factor of 2. Differential scanning calorimetry, high-speed videography, spectroscopy, and microscopy were instrumental in elucidating the factors contributing to this improvement and understanding the role of TiB 2 . While low-temperature TiB 2 oxidation contributed to shorter ignition delays, the combustion characteristics were found to be highly controlled by a heterogeneous gas condensed-phase reaction rather than the flame temperature and materials’ thermal properties. This study demonstrates that the addition of nano-TiB 2 to Al-based thermites holds a significant potential in applications where it is necessary to either lower or finely tune the ignition times. From a manufacturing perspective, this integration technique provides a straightforward approach to enhance the ignition and combustion performance of CuO/Al nanothermites.

Topics & Concepts

ThermiteCombustionIgnition systemMaterials scienceDifferential scanning calorimetryAutoignition temperatureChemical engineeringAluminiumComposite materialThermodynamicsChemistryOrganic chemistryPhysicsEngineeringEnergetic Materials and CombustionRocket and propulsion systems researchThermal and Kinetic Analysis