1. Stable zigzag and tripodal all-nitrogen anion N44− in BeN2
- Author
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Qiwen Jiang, Jiani Lin, Hongyang Zhu, Xiaoli Wang, Zuoqin Zhu, Shitai Guo, and Jianfu Li
- Subjects
010302 applied physics ,Materials science ,Enthalpy ,General Physics and Astronomy ,02 engineering and technology ,Crystal structure ,021001 nanoscience & nanotechnology ,01 natural sciences ,lcsh:QC1-999 ,Standard enthalpy of formation ,Ion ,Crystallography ,Chemical bond ,Zigzag ,0103 physical sciences ,Chemical stability ,0210 nano-technology ,Lone pair ,lcsh:Physics - Abstract
All-nitrogen anions have attracted extensive attention because of their unique chemical and physical properties, and potential applications as high-energy density materials. Here, we discovered two N44- anions with planar zigzag and tripodal structures in BeN2 compound using first-principle calculations with structural search. At ambient conditions, both of them have high kinetic and thermodynamic stability with high energy density (2.48 kJ/g, and 2.95 kJ/g relative to Be3N2 and N2 gas). The zigzag N44− anion has P21/c space group in BeN2 compound and is energetically favorite in the pressure range of 0−48 GPa. While tripodal N44− anion has Cm space group and is energetically favorite in the pressure range of 48−100 GPa. Further analysis of chemical bonding pattern and electronic properties show that the Be atoms provide 2s electrons to alter the bonding state of N44− as well as use empty outer shell 2p orbital to accommodate lone pair electrons of N atoms, forming coordinate bonds to stabilize the compounds. More important, the calculated formation of enthalpies indicate that the zigzag and tripodal N44− can be synthesized via compressing Be3N2 and N2 at a modest pressure. Our results provide a scheme to synthesis N44- anions and stabilize all-nitrogen anions by introducing beryllium atoms.
- Published
- 2019
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