Theoretical Investigation of Energetic Materials Based on Imidazole Framework Featuring Azido/Nitro/Nitrato/Fluoro Groups

IF 1.9 4区化学 Q2 CHEMISTRY, ORGANIC

Journal of Physical Organic Chemistry Pub Date : 2024-10-01 DOI:10.1002/poc.4661

Anjali Sharma, Kshetrimayum Dhruba Singh, Mridula Guin

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Abstract

Development of new high-energy materials (HEMs) is one of the thrust areas of research. These compounds are important for various applications such as propellants, gas generations, explosives in mining, construction, civil and military applications, and safety equipment for national security and defense. HEMs based on imidazole frameworks are currently getting research spotlight due to their exceptional detonation performance with optimum sensitivity. This study reports five imidazole derivatives containing azido/nitro/nitrato/fluoro functional groups. These groups are viable options to design promising explosives with moderate sensitivity. Density functional theory (DFT) method is adopted to determine the geometries, thermodynamic properties, detonation properties, and impact sensitivity of the designed molecules. All the compounds have high density in the range of 1.89–2.03 g/cm³ along with high heat of formation. These compounds aid in new strategy to design HEMs with optimum sensitivity.

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基于叠氮基/硝基/硝基/氟基咪唑骨架的含能材料理论研究

新型高能材料的开发是当前研究的热点之一。这些化合物对于各种应用都很重要，例如推进剂，气体发生器，采矿，建筑，民用和军事应用中的爆炸物以及国家安全和国防的安全设备。以咪唑为骨架的hem具有优异的爆轰性能和最佳的灵敏度，是目前研究的热点。本研究报道了五种含有叠氮/硝基/硝基/氟官能团的咪唑衍生物。这些群体是设计有前景的中等灵敏度炸药的可行选择。采用密度泛函理论（DFT）方法确定了设计分子的几何形状、热力学性质、爆轰性能和冲击灵敏度。所有化合物的密度均在1.89 ~ 2.03 g/cm3之间，形成热较高。这些化合物有助于设计具有最佳灵敏度的hem的新策略。

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来源期刊

Journal of Physical Organic Chemistry 化学-物理化学

CiteScore

3.60

自引率

11.10%

发文量

161

审稿时长

2.3 months

期刊介绍： The Journal of Physical Organic Chemistry is the foremost international journal devoted to the relationship between molecular structure and chemical reactivity in organic systems. It publishes Research Articles, Reviews and Mini Reviews based on research striving to understand the principles governing chemical structures in relation to activity and transformation with physical and mathematical rigor, using results derived from experimental and computational methods. Physical Organic Chemistry is a central and fundamental field with multiple applications in fields such as molecular recognition, supramolecular chemistry, catalysis, photochemistry, biological and material sciences, nanotechnology and surface science.