Miro-hotspot model for the laser initiation of explosive decomposition of energetic materials with melting taken into account

Miro-hotspot model for the laser initiation of explosive decomposition of energetic materials with melting taken into account

In this paper, we study a micro-hotspot model for the laser initiation of explosive decomposition taking into account the melting of the matrix of the energetic material and the nanometallic inclusion contained in its volume. The heating features of the nanoparticle in an inert matrix are investigat...

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Veröffentlicht in:Combustion, explosion, and shock waves explosion, and shock waves, 2014-11, Vol.50 (6), p.704-710
Hauptverfasser: Aduev, B. P., Anan’eva, M. V., Zvekov, A. A., Kalenskii, A. V., Kriger, V. G., Nikitin, A. P.
Format: Artikel
Sprache:eng
Schlagworte:
Classical and Continuum Physics
Classical Mechanics
Control
Decomposition
Dynamical Systems
Energetic materials
Energy density
Engineering
Explosions
Heating
Inclusions
Melting
Nanostructure
Physical Chemistry
Physics
Physics and Astronomy
Vibration
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container_end_page 710
container_issue 6
container_start_page 704
container_title Combustion, explosion, and shock waves
container_volume 50
creator Aduev, B. P.
Anan’eva, M. V.
Zvekov, A. A.
Kalenskii, A. V.
Kriger, V. G.
Nikitin, A. P.
description In this paper, we study a micro-hotspot model for the laser initiation of explosive decomposition taking into account the melting of the matrix of the energetic material and the nanometallic inclusion contained in its volume. The heating features of the nanoparticle in an inert matrix are investigated, and the dependence of the maximum temperature on the surface of the inclusion on its radius is constructed. It is shown that melting leads to a reduction in the maximum heating temperature and a slight change in the radius of the most heated nanoparticle. The dependences of the critical initiation energy density of explosive decomposition of pentaerythritol tetranitrate (PETN) with aluminum nanoparticles on the inclusion radius with and without melting are calculated. With melting taken into account, the model gives higher critical initiation energy density of explosive decomposition. In the case of inclusions of large radius, the formation of the reaction site of explosive decomposition occurs before complete melting of the metal inclusion, which results in solidification of the melt during the induction period.
doi_str_mv 10.1134/S0010508214060112
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The dependences of the critical initiation energy density of explosive decomposition of pentaerythritol tetranitrate (PETN) with aluminum nanoparticles on the inclusion radius with and without melting are calculated. With melting taken into account, the model gives higher critical initiation energy density of explosive decomposition. 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subjects Classical and Continuum Physics
Classical Mechanics
Control
Decomposition
Dynamical Systems
Energetic materials
Energy density
Engineering
Explosions
Heating
Inclusions
Melting
Nanostructure
Physical Chemistry
Physics
Physics and Astronomy
Vibration
title Miro-hotspot model for the laser initiation of explosive decomposition of energetic materials with melting taken into account
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