Synthesis mechanism of four metallic Cyclo-N5− energetic materials: A theoretical Perspective

Author:

Li Xiang123ORCID,Long Yao4ORCID,Zhang Chong5,Sun Chengguo5ORCID,Hu Bingcheng5,Qin Lei123ORCID,Chen Jun4

Affiliation:

1. Key Laboratory of Sensors, Beijing Information Science and Technology University 1 , Beijing 100192, China

2. Key Laboratory of Modern Measurement and Control Technology, Ministry of Education, Beijing Information Science and Technology University 2 , Beijing 100192, China

3. Key Laboratory of Photoelectric Testing Technology, Beijing Information Science and Technology University 3 , Beijing 100192, China

4. Institute of Applied Physics and Computational Mathematics 4 , Beijing 100088, China

5. School of Chemical Engineering, Nanjing University of Science and Technology 5 , Nanjing, Jiangsu 210094, China

Abstract

In the past five years, over 20 types of cyclo-N5− energetic materials (EMs) have been successfully synthesized. Metallic cyclo-N5− EMs exhibit higher density and performance compared to non-metallic cyclo-N5− EMs. However, the mechanisms for such metallic cyclo-N5− EMs remain unexplored. Herein, we performed a thorough quantum chemistry study on the mechanistic pathway for the cyclo-N5− trapped by metal cations in four cyclo-N5− EMs: [Na(H2O) (N5)] · 2H2O, [M(H2O)4(N5)2] · 4H2O (M = Mn, Fe, and Co), by density functional theory methods and transition state theory. During the synthesis process, the cyclo-N5− in the precursor hybrid aromatic compound is susceptible to electrophilic attack by metal cations. This attack disrupts the hydrogen bond interaction surrounding the cyclo-N5−, ultimately leading to the formation of either an ionic bond or a coordination bond between the metal cation and the cyclo-N5−, resulting in an electrophilic substitution reaction. In addition, solvent effects reduce the energy of the ionic bond, thereby promoting the reaction. Our findings will provide valuable insights for future route design and contribute to enhancing the synthesis yield of cyclo-N5− EMs in both theoretical and experimental aspects.

Funder

National Natural Science Foundation of China

Beijing Postdoctoral Science Foundation

Publisher

AIP Publishing

Subject

Physical and Theoretical Chemistry,General Physics and Astronomy

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