How Thermal Aging Affects Ignition and Combustion Properties of Reactive Al/CuO Nanolaminates: A Joint Theoretical/Experimental Study

Estève, Alain; Lahiner, Guillaume; Julien, Baptiste; Vivies, Séverine; Richard, Nicolas; Rossi, Carole

doi:10.3390/nano10102087

Cited by 10 publications

(8 citation statements)

References 34 publications

(45 reference statements)

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“…Obviously, caution must be taken, due to many assumptions associated with the isoconversional methods, but even more from the subtle low temperature aging mechanisms that do not leave an exploitable thermal signature in the DSC traces. Therefore, thermokinetic study must be combined with a precise evaluation of morphological and structural changes at the nanoscale in the nanothemites upon heating as it was recently proposed for nanolaminate systems [36,38]. Such an approach would make it possible to identify the main reactional steps of low temperature, as recorded in the DSC but without any a priori knowledge of their fundaments.…”

Section: Discussionmentioning

confidence: 99%

“…(1 α), limited to independent reactions occurring successively after each other, within specific temperature ranges. However, the thermite reactions, which combines chemical oxido-reduction reactions with mass transport through barrier layers [35][36][37][38] that have dynamical changes in their structures over temperature cannot rigorously be reduced to a single Arrhenius law activation. Thus, we opted for the use of a differential isoconversional method based on the Friedmann method.…”

Section: Thermal Analysis and Kinetic Parameters Of As-prepared Thermite Materialsmentioning

confidence: 99%

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Unexpected enhanced reactivity of aluminized nanothermites by accelerated aging

Lahiner²,

Tenailleau³

et al. 2021

Chemical Engineering Journal

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Section: Discussionmentioning

confidence: 99%

Section: Thermal Analysis and Kinetic Parameters Of As-prepared Thermite Materialsmentioning

confidence: 99%

Unexpected enhanced reactivity of aluminized nanothermites by accelerated aging

Lahiner²,

Tenailleau³

et al. 2021

Chemical Engineering Journal

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“…Beyond the fact that huge discrepancies do exist in diffusion coefficient values in the literature [56][57][58], defining diffusion pathways and associated parameters for both Al and oxygen species of thermite steady state combustion is a vast issue, out of the reach of current understanding. Therefore, it is generally accepted to fit effective coefficients through specific set of measurements, whatever their nature [50,59,60]. We assume diffusion of species to follow a classical Arrhenius law as given in Equation 13 which defines how an Arrhenius law is implemented for species diffusion.…”

Section: Chemistry and Kinetic Treatmentmentioning

confidence: 99%

Modeling the self-propagation reaction in heterogeneous and dense media: Application to Al/CuO thermite

Tichtchenko

Estève

Rossi

2021

Combustion and Flame

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This article provides a computational analysis of the reaction of fully-dense layered aluminum and copper oxide systems. After the detailed presentation of the 2D nonstationary model implementing both oxygen and aluminum diffusion, the propagation of the reaction front in an Al/CuO thin film was studied. The model qualitatively reproduces the dependency of the reaction front progression rate spatially as a function of the fuel concentration. Calculations also evidence the inverse evolution of flame front width with respect to the reaction front velocity. A procedure to estimate the heat loss generated by the fact that the reactants and products may vaporize prior to reaction completion was proposed by imposing a flame temperature limit close to Cu vaporization point. This work also shows that microscopic fluctuations in the instantaneous reaction front velocity can be observed for reactant diffusion activation energy (Ea) of 125 kJ/mol, before quenching for greater Ea. Finally, we demonstrate the potential of this new 2D nonstationary model to investigate the thermal effect of additives such as metallic impurities in the Al/CuO thin film that can lead to the flame front corrugation at the microscale. The simulations show that a metallic particle acts first to boost the reaction velocity as its high thermal conductivity helps the upfront heating. Then, the particle being also a heat sink, a local slowing down of the front velocity is observed. Nomenclature Symbol Meaning Unit C Total concentration of the material (equivalent to a density) kg.m-3 Ci Concentration of the species i kg.m-3 Cp Average specific heat capacity J.kg-1 .K-1 Cp,i Specific heat capacity of the species i J.kg-1 .K-1 Di Diffusion coefficient of the species i m².s-1 Activation energy of the Arrhenius law defining the reaction rate of the copper oxide decomposition J.mol-1 , ℎ Activation energy of the Arrhenius law defining the reaction rate of the copper oxide decomposition J.mol-1 Fs Enthalpy flux related to species flux kg.m-2 .s-1 ℎ , Enthalpy of formation of the species i J.kg-1 0, ℎ Pre-exponential factor of the Arrhenius law defining the reaction rate of the copper oxide decomposition s-1 0, Pre-exponential factor of the Arrhenius law defining the diffusion of the species i m².s-1 L Simulated length µm Lt Total thickness µm n Number of bilayer PHrx Power of reaction W.m-3 PPC Required power for phase change W.m-3 R Gas constant (R=8.314) J.K-1 .mol-1 ri Reaction rate of the species i kg.m-3. s-1 Heat conductivity of the species i W.m-2 .K-1 av Average heat flux going through the heat front W.m-2 av.loss Average heat flux lost by limiting the temperature with Tmax W.m-2

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Section: Figurementioning

confidence: 99%

“…With the batch sizes employed, the total time to produce 60 grams of particles is ≈17 h. Once milled, these particles are expected to retain their reactivity for decades at room temperature, as the microstructure is not so fine that diffusive mixing at room temperature will substantively affect the stored chemical energy. [19,20] In a printed modality, the reactivity of the constituent particles is only part of the equation-the other components comprising the ink will also affect a printed structure's reactivity and properties. Producing an ink incorporating a wide range of particle sizes and morphologies has been demonstrated with sol-gel based inks.…”

mentioning

confidence: 99%

Multifunctional Reactive Nanocomposites via Direct Ink Writing

Arlington

Barron

DeLisio

et al. 2021

Adv Materials Technologies

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3D printing of reactive materials has, to date, primarily focused on controlling reaction velocities and energy release rates by printing novel architectures, which during reaction typically form gaseous and oxide powder products. The utility of printed reactive materials can be increased by designing the material such that its reaction produces both a controlled energy release and a functional product phase without gaseous products. Here, we report the direct ink writing of reactive materials composed of ternary nanocomposite powders that exhibit gasless, exceptionally low velocity reactions. The printed features can be patterned in arbitrary form factors and are brittle and electrically insulating as‐printed. Using a self‐propagating synthesis reaction, these features can be transformed into a mechanically robust, electrically conductive cermet that is capable of handling high currents. This study provides a new paradigm for printing multifunctional reactive materials in which both the energy release of the reaction, as well as the reaction products themselves, are useful for potential applications ranging from printed electronic devices to controlled, directed energy release.

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How Thermal Aging Affects Ignition and Combustion Properties of Reactive Al/CuO Nanolaminates: A Joint Theoretical/Experimental Study

Cited by 10 publications

References 34 publications

Unexpected enhanced reactivity of aluminized nanothermites by accelerated aging

Unexpected enhanced reactivity of aluminized nanothermites by accelerated aging

Modeling the self-propagation reaction in heterogeneous and dense media: Application to Al/CuO thermite

Multifunctional Reactive Nanocomposites via Direct Ink Writing

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