Modular Assembly Drives Synthesis of High-Energy Linked/Fused Molecules

Yanda Jiang; Ning Ding; Qi Sun; Jinyu Chang; Ziteng Zhang; Xudong Xu; Baojing Tian; Chaofeng Zhao; Shenghua Li; Siping Pang

doi:10.1021/acs.orglett.4c04599

Modular Assembly Drives Synthesis of High-Energy Linked/Fused Molecules

Yanda Jiang
, Ning Ding
, Qi Sun^*
, Jinyu Chang
, Ziteng Zhang
, Xudong Xu
, Baojing Tian
, Chaofeng Zhao
, Shenghua Li^*
, Siping Pang^*

^*Corresponding author for this work

Beijing Institute of Technology

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

6 Citations (Scopus)

Abstract

In this study, we propose a “modular assembly” strategy to synthesize a series of new trinitromethyl high-energy molecules. For a typical molecule 1, this approach reduces the number of synthetic steps from 7 to 2 and improves the yield from 1.0% to 48.3%, representing a more than 48-fold increase compared to the traditional “skeleton first, group later” method. All synthesized molecules exhibit exceptional energetic performance, with molecule 1 demonstrating a density of 1.913 g cm^-3, a detonation velocity of 9151 m s^-1, and a thermal decomposition temperature of 177 °C, marking it as highly promising among trinitromethyl high-energy molecules.

Original language	English
Pages (from-to)	4615-4619
Number of pages	5
Journal	Organic Letters
Volume	27
Issue number	18
DOIs	https://doi.org/10.1021/acs.orglett.4c04599
Publication status	Published - 9 May 2025
Externally published	Yes

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10.1021/acs.orglett.4c04599

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title = "Modular Assembly Drives Synthesis of High-Energy Linked/Fused Molecules",

abstract = "In this study, we propose a “modular assembly” strategy to synthesize a series of new trinitromethyl high-energy molecules. For a typical molecule 1, this approach reduces the number of synthetic steps from 7 to 2 and improves the yield from 1.0\% to 48.3\%, representing a more than 48-fold increase compared to the traditional “skeleton first, group later” method. All synthesized molecules exhibit exceptional energetic performance, with molecule 1 demonstrating a density of 1.913 g cm-3, a detonation velocity of 9151 m s-1, and a thermal decomposition temperature of 177 °C, marking it as highly promising among trinitromethyl high-energy molecules.",

author = "Yanda Jiang and Ning Ding and Qi Sun and Jinyu Chang and Ziteng Zhang and Xudong Xu and Baojing Tian and Chaofeng Zhao and Shenghua Li and Siping Pang",

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T1 - Modular Assembly Drives Synthesis of High-Energy Linked/Fused Molecules

AU - Jiang, Yanda

AU - Ding, Ning

AU - Sun, Qi

AU - Chang, Jinyu

AU - Zhang, Ziteng

AU - Xu, Xudong

AU - Tian, Baojing

AU - Zhao, Chaofeng

AU - Li, Shenghua

AU - Pang, Siping

PY - 2025/5/9

Y1 - 2025/5/9

N2 - In this study, we propose a “modular assembly” strategy to synthesize a series of new trinitromethyl high-energy molecules. For a typical molecule 1, this approach reduces the number of synthetic steps from 7 to 2 and improves the yield from 1.0% to 48.3%, representing a more than 48-fold increase compared to the traditional “skeleton first, group later” method. All synthesized molecules exhibit exceptional energetic performance, with molecule 1 demonstrating a density of 1.913 g cm-3, a detonation velocity of 9151 m s-1, and a thermal decomposition temperature of 177 °C, marking it as highly promising among trinitromethyl high-energy molecules.

AB - In this study, we propose a “modular assembly” strategy to synthesize a series of new trinitromethyl high-energy molecules. For a typical molecule 1, this approach reduces the number of synthetic steps from 7 to 2 and improves the yield from 1.0% to 48.3%, representing a more than 48-fold increase compared to the traditional “skeleton first, group later” method. All synthesized molecules exhibit exceptional energetic performance, with molecule 1 demonstrating a density of 1.913 g cm-3, a detonation velocity of 9151 m s-1, and a thermal decomposition temperature of 177 °C, marking it as highly promising among trinitromethyl high-energy molecules.

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DO - 10.1021/acs.orglett.4c04599

M3 - Article

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VL - 27

SP - 4615

EP - 4619

JO - Organic Letters

JF - Organic Letters

IS - 18

ER -

Modular Assembly Drives Synthesis of High-Energy Linked/Fused Molecules

Abstract

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