What question did this study set out to answer?

The study aims to develop high-performance energetic materials with favorable properties through an innovative hydrogen atom transfer strategy.

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March 25, 2026

Electronic-Structure-Regulated Hydrogen Atom Transfer for the Construction of High-Performance Nitroimino-Functionalized Fused Heterocyclic Energetic Materials

Key Points

The study aims to develop high-performance energetic materials with favorable properties through an innovative hydrogen atom transfer strategy.
Developed a fused heterocyclic compound using an electronically self-regulated hydrogen atom transfer.
Integrated a -NH2/-NO2/-NH2 motif into a [1,2,4]triazolo[4,3-b]pyridazine scaffold.
Triggered in situ hydrogen atom transfer followed by nitration of the amino group.
Compound 6 shows detonation velocity of 8896 m s-1.
Demonstrates pressure of 32.4 GPa.
Exhibits low sensitivity and good molecular stability.

Abstract

Balancing high energy density with low sensitivity remains a key challenge in the development of advanced energetic materials. Here, we present an electronically self-regulation-driven hydrogen atom transfer strategy for the construction of fused heterocyclic energetic compounds. By integration of an alternating -NH2/-NO2/-NH2 motif into a 1,2,4triazolo4,3-bpyridazine scaffold, an in situ hydrogen atom transfer was triggered, enabling subsequent nitration of the amino group to generate a nitroimino functionality. Based on this strategy, compound 6 exhibits excellent detonation properties (D = 8896 m s-1 and P = 32.4 GPa) with low sensitivity and good molecular stability, demonstrating its promising application potential as an energetic material.

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Electronic-Structure-Regulated Hydrogen Atom Transfer for the Construction of High-Performance Nitroimino-Functionalized Fused Heterocyclic Energetic Materials

Key Points

Abstract

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