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Pressure-Driven Ne-Bearing Polynitrides with Ultrahigh Energy Density

2022; Institute of Physics; Volume: 39; Issue: 5 Linguagem: Inglês

10.1088/0256-307x/39/5/056102

1741-3540

Lulu Liu, Shoutao Zhang, Haijun Zhang,

High-pressure geophysics and materials

Neon (Ne) can reveal the evolution of planets, and nitrogen (N) is the most abundant element in the Earth’s atmosphere. Considering the inertness of neon, whether nitrogen and neon can react has aroused great interest in condensed matter physics and space science. Here, we identify three new Ne–N compounds (i.e., NeN 6 , NeN 10 , and NeN 22 ) under pressure by first-principles calculations. We find that inserting Ne into N 2 substantially decreases the polymeric pressure of the nitrogen and promotes the formation of abundant polynitrogen structures. Especially, NeN 22 acquires a duplex host-guest structure, in which guest atoms (Ne and N 2 dimers) are trapped inside the crystalline host N 20 cages. Importantly, both NeN 10 and NeN 22 not only are dynamically and mechanically stable but also have a high thermal stability up to 500 K under ambient pressure. Moreover, ultra-high energy densities are obtained in NeN 10 (11.1 kJ/g), NeN 22 (11.5 kJ/g), tetragonal t-N 22 (11.6 kJ/g), and t-N 20 (12.0 kJ/g) produced from NeN 22 , which are more than twice the value of trinitrotoluene (TNT). Meanwhile, their explosive performance is superior to that of TNT. Therefore, NeN 10 , NeN 22 , t-N 22 , and t-N 20 are promising green high-energy-density materials. This work promotes the study of neon-nitrogen compounds with superior properties and potential applications.