Unprecedented energetic zwitterion integrating thermal stability, high energy density and low sensitivity: Overcoming performance trade-offs in conventional energetic materials

Bojun Tan; Xiong Yang; Jinkang Dou; Jian Su; Jing Zhang; Siwei Song; Changwei Tang; Minghui Xu; Shu Zeng; Wenjie Li; Jieyu Luan; Gen Zhang; Qinghua Zhang; Xianming Lu; Bozhou Wang; Ning Liu

doi:10.1016/j.dt.2025.05.024

Unprecedented energetic zwitterion integrating thermal stability, high energy density and low sensitivity: Overcoming performance trade-offs in conventional energetic materials

Bojun Tan, Xiong Yang, Jinkang Dou, Jian Su, Jing Zhang, Siwei Song, Changwei Tang, Minghui Xu, Shu Zeng, Wenjie Li, Jieyu Luan, Gen Zhang, Qinghua Zhang, Xianming Lu, Bozhou Wang, Ning Liu

航天学院

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

The simultaneous integration of high energy density, low sensitivity, and thermal stability in energetic materials has constituted a century-long scientific challenge. Herein, we address this through a dual-zwitterionic electronic delocalization strategy, yielding TYX-3, the first bis-inner salt triazolo-tetrazine framework combining these mutually exclusive properties. Uniform π-electron distribution and elevated bond dissociation energy confer exceptional thermal stability (T_d = 365 °C) with TATB-level insensitivity (impact sensitivity IS > 40 J, friction sensitivity FS > 360 N). Engineered π-stacked networks enable record density (1.99 g·cm⁻³) with detonation performance surpassing HMX benchmarks (detonation velocity 9315 m·s⁻¹, detonation pressure 36.6 GPa). Practical implementation in Poly (3-nitratomethyl-3-methyloxetane) (PNMMFO) solid propellants demonstrates 5.4-fold safety enhancement over conventional HMX-based formulations while maintaining equivalent specific impulse. This work establishes a new design paradigm for energetic materials, overcoming the historical trade-offs between molecular stability and energy output through rational zwitterionic engineering.

源语言	英语
期刊	Defence Technology
DOI	https://doi.org/10.1016/j.dt.2025.05.024
出版状态	已接受/待刊 - 2025

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10.1016/j.dt.2025.05.024

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引用此

Tan, B., Yang, X., Dou, J., Su, J., Zhang, J., Song, S., Tang, C., Xu, M., Zeng, S., Li, W., Luan, J., Zhang, G., Zhang, Q., Lu, X., Wang, B., & Liu, N. (已接受/印刷中). Unprecedented energetic zwitterion integrating thermal stability, high energy density and low sensitivity: Overcoming performance trade-offs in conventional energetic materials. Defence Technology. https://doi.org/10.1016/j.dt.2025.05.024

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title = "Unprecedented energetic zwitterion integrating thermal stability, high energy density and low sensitivity: Overcoming performance trade-offs in conventional energetic materials",

abstract = "The simultaneous integration of high energy density, low sensitivity, and thermal stability in energetic materials has constituted a century-long scientific challenge. Herein, we address this through a dual-zwitterionic electronic delocalization strategy, yielding TYX-3, the first bis-inner salt triazolo-tetrazine framework combining these mutually exclusive properties. Uniform π-electron distribution and elevated bond dissociation energy confer exceptional thermal stability (Td = 365 °C) with TATB-level insensitivity (impact sensitivity IS > 40 J, friction sensitivity FS > 360 N). Engineered π-stacked networks enable record density (1.99 g·cm−3) with detonation performance surpassing HMX benchmarks (detonation velocity 9315 m·s−1, detonation pressure 36.6 GPa). Practical implementation in Poly (3-nitratomethyl-3-methyloxetane) (PNMMFO) solid propellants demonstrates 5.4-fold safety enhancement over conventional HMX-based formulations while maintaining equivalent specific impulse. This work establishes a new design paradigm for energetic materials, overcoming the historical trade-offs between molecular stability and energy output through rational zwitterionic engineering.",

keywords = "Energetic materials, High energy density, Solid propellants, Thermal stability, Triazolo-tetrazine framework",

author = "Bojun Tan and Xiong Yang and Jinkang Dou and Jian Su and Jing Zhang and Siwei Song and Changwei Tang and Minghui Xu and Shu Zeng and Wenjie Li and Jieyu Luan and Gen Zhang and Qinghua Zhang and Xianming Lu and Bozhou Wang and Ning Liu",

note = "Publisher Copyright: {\textcopyright} 2025 China Ordnance Society",

year = "2025",

doi = "10.1016/j.dt.2025.05.024",

language = "英语",

journal = "Defence Technology",

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Tan, B, Yang, X, Dou, J, Su, J, Zhang, J, Song, S, Tang, C, Xu, M, Zeng, S, Li, W, Luan, J, Zhang, G, Zhang, Q, Lu, X, Wang, B & Liu, N 2025, 'Unprecedented energetic zwitterion integrating thermal stability, high energy density and low sensitivity: Overcoming performance trade-offs in conventional energetic materials', Defence Technology. https://doi.org/10.1016/j.dt.2025.05.024

TY - JOUR

T1 - Unprecedented energetic zwitterion integrating thermal stability, high energy density and low sensitivity

T2 - Overcoming performance trade-offs in conventional energetic materials

AU - Tan, Bojun

AU - Yang, Xiong

AU - Dou, Jinkang

AU - Su, Jian

AU - Zhang, Jing

AU - Song, Siwei

AU - Tang, Changwei

AU - Xu, Minghui

AU - Zeng, Shu

AU - Li, Wenjie

AU - Luan, Jieyu

AU - Zhang, Gen

AU - Zhang, Qinghua

AU - Lu, Xianming

AU - Wang, Bozhou

AU - Liu, Ning

PY - 2025

Y1 - 2025

N2 - The simultaneous integration of high energy density, low sensitivity, and thermal stability in energetic materials has constituted a century-long scientific challenge. Herein, we address this through a dual-zwitterionic electronic delocalization strategy, yielding TYX-3, the first bis-inner salt triazolo-tetrazine framework combining these mutually exclusive properties. Uniform π-electron distribution and elevated bond dissociation energy confer exceptional thermal stability (Td = 365 °C) with TATB-level insensitivity (impact sensitivity IS > 40 J, friction sensitivity FS > 360 N). Engineered π-stacked networks enable record density (1.99 g·cm−3) with detonation performance surpassing HMX benchmarks (detonation velocity 9315 m·s−1, detonation pressure 36.6 GPa). Practical implementation in Poly (3-nitratomethyl-3-methyloxetane) (PNMMFO) solid propellants demonstrates 5.4-fold safety enhancement over conventional HMX-based formulations while maintaining equivalent specific impulse. This work establishes a new design paradigm for energetic materials, overcoming the historical trade-offs between molecular stability and energy output through rational zwitterionic engineering.

AB - The simultaneous integration of high energy density, low sensitivity, and thermal stability in energetic materials has constituted a century-long scientific challenge. Herein, we address this through a dual-zwitterionic electronic delocalization strategy, yielding TYX-3, the first bis-inner salt triazolo-tetrazine framework combining these mutually exclusive properties. Uniform π-electron distribution and elevated bond dissociation energy confer exceptional thermal stability (Td = 365 °C) with TATB-level insensitivity (impact sensitivity IS > 40 J, friction sensitivity FS > 360 N). Engineered π-stacked networks enable record density (1.99 g·cm−3) with detonation performance surpassing HMX benchmarks (detonation velocity 9315 m·s−1, detonation pressure 36.6 GPa). Practical implementation in Poly (3-nitratomethyl-3-methyloxetane) (PNMMFO) solid propellants demonstrates 5.4-fold safety enhancement over conventional HMX-based formulations while maintaining equivalent specific impulse. This work establishes a new design paradigm for energetic materials, overcoming the historical trade-offs between molecular stability and energy output through rational zwitterionic engineering.

KW - Energetic materials

KW - High energy density

KW - Solid propellants

KW - Thermal stability

KW - Triazolo-tetrazine framework

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U2 - 10.1016/j.dt.2025.05.024

DO - 10.1016/j.dt.2025.05.024

M3 - 文章

AN - SCOPUS:105008014379

SN - 2096-3459

JO - Defence Technology

JF - Defence Technology

ER -