Substituent effects on the properties related to detonation performance and stability for pentaprismane derivatives

Wei Jie Chi; Yan Yan Guo; Quan Song Li; Ze Sheng Li

doi:10.1007/s00214-016-1885-x

Substituent effects on the properties related to detonation performance and stability for pentaprismane derivatives

Wei Jie Chi, Yan Yan Guo, Quan Song Li^*, Ze Sheng Li

^*Corresponding author for this work

School of Chemistry and Chemical Engineering

Beijing Institute of Technology

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

3 Citations (Scopus)

Abstract

Density functional theory calculations were used to study energetic and stability properties for a series of pentaprismane (C₁₀H₁₀) derivatives with different substituent groups (NO₂, NO, CN, N₃, NH₂, NHNO₂, and ONO₂). The results indicated that the N₃ and CN groups greatly increase while the ONO₂ group decreases the heats of formation. Moreover, the NO₂, NHNO₂, and ONO₂ derivatives possess better detonation properties (detonation velocities = 8.92–9.72 km s⁻¹ and detonation pressures = 38.37–45.24 GPa) than those of other derivatives due to high densities (1.97–2.08 g cm⁻³) and large heats of detonation (1189.22–1807.45 kJ mol⁻¹). An analysis of the bond dissociation energies (BDE) revealed that all investigated compounds meet the qualification of energetic material (BDE > 84 kJ mol⁻¹) even though the initiation decomposition steps are diverse (breaking of C–C bonds for NO₂, N₃, NH₂, and CN derivatives, N–NO₂ bond for NHNO₂ derivative, O–NO₂ bond for ONO₂ derivative, and cage–NO bond for NO derivative). Considering both detonation performance and thermal stability, NO₂ and NHNO₂ derivatives are proposed to be potential candidates of high energy density materials.

Original language	English
Article number	145
Journal	Theoretical Chemistry Accounts
Volume	135
Issue number	6
DOIs	https://doi.org/10.1007/s00214-016-1885-x
Publication status	Published - 1 Jun 2016

Keywords

Density functional theory
Detonation properties
High energy density compounds
Pentaprismane derivatives
Thermal stability

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Chi, W. J., Guo, Y. Y., Li, Q. S., & Li, Z. S. (2016). Substituent effects on the properties related to detonation performance and stability for pentaprismane derivatives. Theoretical Chemistry Accounts, 135(6), Article 145. https://doi.org/10.1007/s00214-016-1885-x

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title = "Substituent effects on the properties related to detonation performance and stability for pentaprismane derivatives",

abstract = "Density functional theory calculations were used to study energetic and stability properties for a series of pentaprismane (C10H10) derivatives with different substituent groups (NO2, NO, CN, N3, NH2, NHNO2, and ONO2). The results indicated that the N3 and CN groups greatly increase while the ONO2 group decreases the heats of formation. Moreover, the NO2, NHNO2, and ONO2 derivatives possess better detonation properties (detonation velocities = 8.92–9.72 km s−1 and detonation pressures = 38.37–45.24 GPa) than those of other derivatives due to high densities (1.97–2.08 g cm−3) and large heats of detonation (1189.22–1807.45 kJ mol−1). An analysis of the bond dissociation energies (BDE) revealed that all investigated compounds meet the qualification of energetic material (BDE > 84 kJ mol−1) even though the initiation decomposition steps are diverse (breaking of C–C bonds for NO2, N3, NH2, and CN derivatives, N–NO2 bond for NHNO2 derivative, O–NO2 bond for ONO2 derivative, and cage–NO bond for NO derivative). Considering both detonation performance and thermal stability, NO2 and NHNO2 derivatives are proposed to be potential candidates of high energy density materials.",

keywords = "Density functional theory, Detonation properties, High energy density compounds, Pentaprismane derivatives, Thermal stability",

author = "Chi, {Wei Jie} and Guo, {Yan Yan} and Li, {Quan Song} and Li, {Ze Sheng}",

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T1 - Substituent effects on the properties related to detonation performance and stability for pentaprismane derivatives

AU - Chi, Wei Jie

AU - Guo, Yan Yan

AU - Li, Quan Song

AU - Li, Ze Sheng

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Density functional theory calculations were used to study energetic and stability properties for a series of pentaprismane (C10H10) derivatives with different substituent groups (NO2, NO, CN, N3, NH2, NHNO2, and ONO2). The results indicated that the N3 and CN groups greatly increase while the ONO2 group decreases the heats of formation. Moreover, the NO2, NHNO2, and ONO2 derivatives possess better detonation properties (detonation velocities = 8.92–9.72 km s−1 and detonation pressures = 38.37–45.24 GPa) than those of other derivatives due to high densities (1.97–2.08 g cm−3) and large heats of detonation (1189.22–1807.45 kJ mol−1). An analysis of the bond dissociation energies (BDE) revealed that all investigated compounds meet the qualification of energetic material (BDE > 84 kJ mol−1) even though the initiation decomposition steps are diverse (breaking of C–C bonds for NO2, N3, NH2, and CN derivatives, N–NO2 bond for NHNO2 derivative, O–NO2 bond for ONO2 derivative, and cage–NO bond for NO derivative). Considering both detonation performance and thermal stability, NO2 and NHNO2 derivatives are proposed to be potential candidates of high energy density materials.

AB - Density functional theory calculations were used to study energetic and stability properties for a series of pentaprismane (C10H10) derivatives with different substituent groups (NO2, NO, CN, N3, NH2, NHNO2, and ONO2). The results indicated that the N3 and CN groups greatly increase while the ONO2 group decreases the heats of formation. Moreover, the NO2, NHNO2, and ONO2 derivatives possess better detonation properties (detonation velocities = 8.92–9.72 km s−1 and detonation pressures = 38.37–45.24 GPa) than those of other derivatives due to high densities (1.97–2.08 g cm−3) and large heats of detonation (1189.22–1807.45 kJ mol−1). An analysis of the bond dissociation energies (BDE) revealed that all investigated compounds meet the qualification of energetic material (BDE > 84 kJ mol−1) even though the initiation decomposition steps are diverse (breaking of C–C bonds for NO2, N3, NH2, and CN derivatives, N–NO2 bond for NHNO2 derivative, O–NO2 bond for ONO2 derivative, and cage–NO bond for NO derivative). Considering both detonation performance and thermal stability, NO2 and NHNO2 derivatives are proposed to be potential candidates of high energy density materials.

KW - Density functional theory

KW - Detonation properties

KW - High energy density compounds

KW - Pentaprismane derivatives

KW - Thermal stability

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JO - Theoretical Chemistry Accounts

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Substituent effects on the properties related to detonation performance and stability for pentaprismane derivatives

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