In this work, the confinement of an N−3 azide anion inside finite-size single-wall zigzag and armchair car- bon nanotubes of different diameters has been studied by wave function and density functional theory. Unrelaxed and relaxed interaction energies have been computed, resulting in a favorable interaction between the guest and host sys- tem. In particular, the largest interaction has been observed for the confinement in an armchair (5, 5) carbon nanotube, for which a natural population analysis as well as an inves- tigation based on the molecular electrostatic potential has been carried out. The nature of the interaction between the two fragments appears to be mainly electrostatic, favored by the enhanced polarizability of the nanotube wall treated as a finite system and passivated by hydrogen atoms. The results obtained are promising for possible applications of this complex as a starting point for the stabilization of larger polynitrogen compounds, suitable as a high-energy density material.

N 3− azide anion confined inside finite-size carbon nanotubes

Battaglia, Stefano;Evangelisti, Stefano;Faginas-Lago, Noelia;
2017

Abstract

In this work, the confinement of an N−3 azide anion inside finite-size single-wall zigzag and armchair car- bon nanotubes of different diameters has been studied by wave function and density functional theory. Unrelaxed and relaxed interaction energies have been computed, resulting in a favorable interaction between the guest and host sys- tem. In particular, the largest interaction has been observed for the confinement in an armchair (5, 5) carbon nanotube, for which a natural population analysis as well as an inves- tigation based on the molecular electrostatic potential has been carried out. The nature of the interaction between the two fragments appears to be mainly electrostatic, favored by the enhanced polarizability of the nanotube wall treated as a finite system and passivated by hydrogen atoms. The results obtained are promising for possible applications of this complex as a starting point for the stabilization of larger polynitrogen compounds, suitable as a high-energy density material.
2017
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11391/1424915
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