A High-Density, Thermally Stable Energetic Compound: Strategic Integration of Furazan and Triazole Rings via a C–N Methylene Bridge

Yangyang Long; Man Xu; Qi Lai; Ping Yin; Siping Pang

doi:10.1021/acs.joc.5c02905

A High-Density, Thermally Stable Energetic Compound: Strategic Integration of Furazan and Triazole Rings via a C–N Methylene Bridge

Yangyang Long
, Man Xu
, Qi Lai^*
, Ping Yin^*
, Siping Pang^*

^*Corresponding author for this work

School of Material Science and Engineering

Beijing Institute of Technology

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

Abstract

The development of energetic materials that simultaneously achieve high energy density and low sensitivity remains a challenging objective. This study presents the synthesis and characterization of a novel C–N methylene bridged compound, 2, strategically integrating the backbones of furazan with 1,2,4-triazole. This molecular design exploits the high nitrogen–oxygen content of furazan and the stability of triazole, while further nitration enhances the overall performance. Compound 2 exhibits an outstanding balance of energetic properties and molecular stability, featuring a high density (1.84 g·cm–3), superior thermal stability (Td = 267 °C), and remarkable insensitivity (IS > 40 J). Its calculated detonation performance (D = 8425 m·s–1, P = 29.51 GPa) surpasses that of the classic explosive TNT. This work demonstrates the C–N methylene bridging strategy as a highly effective approach for designing high-performance and low-sensitivity energetic materials.

Original language	English
Pages (from-to)	4163-4169
Number of pages	7
Journal	Journal of Organic Chemistry
Volume	91
Issue number	12
DOIs	https://doi.org/10.1021/acs.joc.5c02905
Publication status	Published - 27 Mar 2026

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title = "A High-Density, Thermally Stable Energetic Compound: Strategic Integration of Furazan and Triazole Rings via a C–N Methylene Bridge",

abstract = "The development of energetic materials that simultaneously achieve high energy density and low sensitivity remains a challenging objective. This study presents the synthesis and characterization of a novel C–N methylene bridged compound, 2, strategically integrating the backbones of furazan with 1,2,4-triazole. This molecular design exploits the high nitrogen–oxygen content of furazan and the stability of triazole, while further nitration enhances the overall performance. Compound 2 exhibits an outstanding balance of energetic properties and molecular stability, featuring a high density (1.84 g·cm–3), superior thermal stability (Td = 267 °C), and remarkable insensitivity (IS > 40 J). Its calculated detonation performance (D = 8425 m·s–1, P = 29.51 GPa) surpasses that of the classic explosive TNT. This work demonstrates the C–N methylene bridging strategy as a highly effective approach for designing high-performance and low-sensitivity energetic materials.",

author = "Yangyang Long and Man Xu and Qi Lai and Ping Yin and Siping Pang",

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T1 - A High-Density, Thermally Stable Energetic Compound

T2 - Strategic Integration of Furazan and Triazole Rings via a C–N Methylene Bridge

AU - Long, Yangyang

AU - Xu, Man

AU - Lai, Qi

AU - Yin, Ping

AU - Pang, Siping

PY - 2026/3/27

Y1 - 2026/3/27

N2 - The development of energetic materials that simultaneously achieve high energy density and low sensitivity remains a challenging objective. This study presents the synthesis and characterization of a novel C–N methylene bridged compound, 2, strategically integrating the backbones of furazan with 1,2,4-triazole. This molecular design exploits the high nitrogen–oxygen content of furazan and the stability of triazole, while further nitration enhances the overall performance. Compound 2 exhibits an outstanding balance of energetic properties and molecular stability, featuring a high density (1.84 g·cm–3), superior thermal stability (Td = 267 °C), and remarkable insensitivity (IS > 40 J). Its calculated detonation performance (D = 8425 m·s–1, P = 29.51 GPa) surpasses that of the classic explosive TNT. This work demonstrates the C–N methylene bridging strategy as a highly effective approach for designing high-performance and low-sensitivity energetic materials.

AB - The development of energetic materials that simultaneously achieve high energy density and low sensitivity remains a challenging objective. This study presents the synthesis and characterization of a novel C–N methylene bridged compound, 2, strategically integrating the backbones of furazan with 1,2,4-triazole. This molecular design exploits the high nitrogen–oxygen content of furazan and the stability of triazole, while further nitration enhances the overall performance. Compound 2 exhibits an outstanding balance of energetic properties and molecular stability, featuring a high density (1.84 g·cm–3), superior thermal stability (Td = 267 °C), and remarkable insensitivity (IS > 40 J). Its calculated detonation performance (D = 8425 m·s–1, P = 29.51 GPa) surpasses that of the classic explosive TNT. This work demonstrates the C–N methylene bridging strategy as a highly effective approach for designing high-performance and low-sensitivity energetic materials.

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JO - Journal of Organic Chemistry

JF - Journal of Organic Chemistry

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ER -

A High-Density, Thermally Stable Energetic Compound: Strategic Integration of Furazan and Triazole Rings via a C–N Methylene Bridge

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