Elucidation of the dynamics for hot-spot initiation at nonuniform interfaces of highly shocked materials

Qi An; Sergey V. Zybin; William A. Goddard; Andres Jaramillo-Botero; Mario Blanco; Sheng Nian Luo

doi:10.1103/PhysRevB.84.220101

Elucidation of the dynamics for hot-spot initiation at nonuniform interfaces of highly shocked materials

Qi An
, Sergey V. Zybin
, William A. Goddard
, Andres Jaramillo-Botero
, Mario Blanco
, Sheng Nian Luo

Research output: Contribution to journal › Article › peer-review

109 Scopus citations

Abstract

The fundamental processes in shock-induced instabilities of materials remain obscure, particularly for detonation of energetic materials. We simulated these processes at the atomic scale on a realistic model of a polymer-bonded explosive (3,695,375 atoms/cell) and observed that a hot spot forms at the nonuniform interface, arising from shear relaxation that results in shear along the interface that leads to a large temperature increase that persists long after the shock front has passed the interface. For energetic materials this temperature increase is coupled to chemical reactions that lead to detonation. We show that decreasing the density of the binder eliminates the hot spot.

Original language	English
Article number	220101
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	84
Issue number	22
DOIs	https://doi.org/10.1103/PhysRevB.84.220101
State	Published - 07 Dec 2011
Externally published	Yes

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10.1103/PhysRevB.84.220101

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title = "Elucidation of the dynamics for hot-spot initiation at nonuniform interfaces of highly shocked materials",

abstract = "The fundamental processes in shock-induced instabilities of materials remain obscure, particularly for detonation of energetic materials. We simulated these processes at the atomic scale on a realistic model of a polymer-bonded explosive (3,695,375 atoms/cell) and observed that a hot spot forms at the nonuniform interface, arising from shear relaxation that results in shear along the interface that leads to a large temperature increase that persists long after the shock front has passed the interface. For energetic materials this temperature increase is coupled to chemical reactions that lead to detonation. We show that decreasing the density of the binder eliminates the hot spot.",

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AU - An, Qi

AU - Zybin, Sergey V.

AU - Goddard, William A.

AU - Jaramillo-Botero, Andres

AU - Blanco, Mario

AU - Luo, Sheng Nian

PY - 2011/12/7

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N2 - The fundamental processes in shock-induced instabilities of materials remain obscure, particularly for detonation of energetic materials. We simulated these processes at the atomic scale on a realistic model of a polymer-bonded explosive (3,695,375 atoms/cell) and observed that a hot spot forms at the nonuniform interface, arising from shear relaxation that results in shear along the interface that leads to a large temperature increase that persists long after the shock front has passed the interface. For energetic materials this temperature increase is coupled to chemical reactions that lead to detonation. We show that decreasing the density of the binder eliminates the hot spot.

AB - The fundamental processes in shock-induced instabilities of materials remain obscure, particularly for detonation of energetic materials. We simulated these processes at the atomic scale on a realistic model of a polymer-bonded explosive (3,695,375 atoms/cell) and observed that a hot spot forms at the nonuniform interface, arising from shear relaxation that results in shear along the interface that leads to a large temperature increase that persists long after the shock front has passed the interface. For energetic materials this temperature increase is coupled to chemical reactions that lead to detonation. We show that decreasing the density of the binder eliminates the hot spot.

UR - https://www.scopus.com/pages/publications/84855306509

U2 - 10.1103/PhysRevB.84.220101

DO - 10.1103/PhysRevB.84.220101

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JF - Physical Review B - Condensed Matter and Materials Physics

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M1 - 220101

ER -

Elucidation of the dynamics for hot-spot initiation at nonuniform interfaces of highly shocked materials

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