Predicting impact sensitivity of energetic materials: insights from energy transfer of carriers

Wei Hong Liu; Qi Jun Liu; Mi Zhong; Yun Dan Gan; Fu Sheng Liu; Xing Han Li; Bin Tang

doi:10.1016/j.actamat.2022.118137

Predicting impact sensitivity of energetic materials: insights from energy transfer of carriers

Wei Hong Liu, Qi Jun Liu, Mi Zhong, Yun Dan Gan, Fu Sheng Liu, Xing Han Li, Bin Tang

材料学院

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摘要

The impact sensitivity to external stimuli is a critical parameter to evaluate and design high-performance energetic materials (EMs). Investigating factors that affect sensitivity and further revealing the sensitivity mechanism are still huge challenges. In the present study, a physical model is established to assess impact sensitivity of 16 energetic compounds based on the energy transfer of carriers using first-principles calculation. The results show that the empirical parameter ψ obtained by considering the band gap, the density of states, and the ability of electronic migration has a remarkable correlation with experimental drop energy E₅₀. This is in favor of the basic assumption that the energetic material would be less sensitive if the electrons transfer energies quickly to other molecules, making it harder to form a hot spot.

源语言	英语
文章编号	118137
期刊	Acta Materialia
卷	236
DOI	https://doi.org/10.1016/j.actamat.2022.118137
出版状态	已出版 - 1 9月 2022

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title = "Predicting impact sensitivity of energetic materials: insights from energy transfer of carriers",

abstract = "The impact sensitivity to external stimuli is a critical parameter to evaluate and design high-performance energetic materials (EMs). Investigating factors that affect sensitivity and further revealing the sensitivity mechanism are still huge challenges. In the present study, a physical model is established to assess impact sensitivity of 16 energetic compounds based on the energy transfer of carriers using first-principles calculation. The results show that the empirical parameter ψ obtained by considering the band gap, the density of states, and the ability of electronic migration has a remarkable correlation with experimental drop energy E50. This is in favor of the basic assumption that the energetic material would be less sensitive if the electrons transfer energies quickly to other molecules, making it harder to form a hot spot.",

keywords = "Electronic properties, Energetic materials, Energy conduction, Impact sensitivity",

author = "Liu, {Wei Hong} and Liu, {Qi Jun} and Mi Zhong and Gan, {Yun Dan} and Liu, {Fu Sheng} and Li, {Xing Han} and Bin Tang",

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year = "2022",

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doi = "10.1016/j.actamat.2022.118137",

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TY - JOUR

T1 - Predicting impact sensitivity of energetic materials

T2 - insights from energy transfer of carriers

AU - Liu, Wei Hong

AU - Liu, Qi Jun

AU - Zhong, Mi

AU - Gan, Yun Dan

AU - Liu, Fu Sheng

AU - Li, Xing Han

AU - Tang, Bin

PY - 2022/9/1

Y1 - 2022/9/1

N2 - The impact sensitivity to external stimuli is a critical parameter to evaluate and design high-performance energetic materials (EMs). Investigating factors that affect sensitivity and further revealing the sensitivity mechanism are still huge challenges. In the present study, a physical model is established to assess impact sensitivity of 16 energetic compounds based on the energy transfer of carriers using first-principles calculation. The results show that the empirical parameter ψ obtained by considering the band gap, the density of states, and the ability of electronic migration has a remarkable correlation with experimental drop energy E50. This is in favor of the basic assumption that the energetic material would be less sensitive if the electrons transfer energies quickly to other molecules, making it harder to form a hot spot.

AB - The impact sensitivity to external stimuli is a critical parameter to evaluate and design high-performance energetic materials (EMs). Investigating factors that affect sensitivity and further revealing the sensitivity mechanism are still huge challenges. In the present study, a physical model is established to assess impact sensitivity of 16 energetic compounds based on the energy transfer of carriers using first-principles calculation. The results show that the empirical parameter ψ obtained by considering the band gap, the density of states, and the ability of electronic migration has a remarkable correlation with experimental drop energy E50. This is in favor of the basic assumption that the energetic material would be less sensitive if the electrons transfer energies quickly to other molecules, making it harder to form a hot spot.

KW - Electronic properties

KW - Energetic materials

KW - Energy conduction

KW - Impact sensitivity

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DO - 10.1016/j.actamat.2022.118137

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VL - 236

JO - Acta Materialia

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Predicting impact sensitivity of energetic materials: insights from energy transfer of carriers

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