Amorphous polymerization of nitrogen in compressed cupric azide

Yujia Xu; Weijing Zhang; Tonglai Zhang; Wei Guo; L. Yongjun

doi:10.1002/jcc.26150

Amorphous polymerization of nitrogen in compressed cupric azide

Yujia Xu, Weijing Zhang, Tonglai Zhang, Wei Guo, L. Yongjun

School of Physics

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

Metal azides have attracted increasing attention as precursors for synthesizing polymeric nitrogen. In this article, we report the amorphous polymerization of nitrogen by compressing cupric azide. The ab initio molecular dynamics simulations show that crystalline cupric azide transforms into a disordered network composed of singly bonded nitrogen at a hydrostatic pressure of 40 GPa and room temperature. The transformation manifests the formation of a π delocalization along the disordered Cu-N network, thus resulting in a semiconductor–metal transition. The estimated heat of formation of the amorphous polymeric nitrogen system is comparable to conventional high-energy-density materials. The amorphization provides an alternative route to the polymerization of nitrogen under moderate conditions.

Original language	English
Pages (from-to)	1026-1033
Number of pages	8
Journal	Journal of Computational Chemistry
Volume	41
Issue number	10
DOIs	https://doi.org/10.1002/jcc.26150
Publication status	Published - 15 Apr 2020

Keywords

ab initio molecular dynamics
amorphization
azides
polynitrogen

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10.1002/jcc.26150

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title = "Amorphous polymerization of nitrogen in compressed cupric azide",

abstract = "Metal azides have attracted increasing attention as precursors for synthesizing polymeric nitrogen. In this article, we report the amorphous polymerization of nitrogen by compressing cupric azide. The ab initio molecular dynamics simulations show that crystalline cupric azide transforms into a disordered network composed of singly bonded nitrogen at a hydrostatic pressure of 40 GPa and room temperature. The transformation manifests the formation of a π delocalization along the disordered Cu-N network, thus resulting in a semiconductor–metal transition. The estimated heat of formation of the amorphous polymeric nitrogen system is comparable to conventional high-energy-density materials. The amorphization provides an alternative route to the polymerization of nitrogen under moderate conditions.",

keywords = "ab initio molecular dynamics, amorphization, azides, polynitrogen",

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AU - Xu, Yujia

AU - Zhang, Weijing

AU - Zhang, Tonglai

AU - Guo, Wei

AU - Yongjun, L.

PY - 2020/4/15

Y1 - 2020/4/15

N2 - Metal azides have attracted increasing attention as precursors for synthesizing polymeric nitrogen. In this article, we report the amorphous polymerization of nitrogen by compressing cupric azide. The ab initio molecular dynamics simulations show that crystalline cupric azide transforms into a disordered network composed of singly bonded nitrogen at a hydrostatic pressure of 40 GPa and room temperature. The transformation manifests the formation of a π delocalization along the disordered Cu-N network, thus resulting in a semiconductor–metal transition. The estimated heat of formation of the amorphous polymeric nitrogen system is comparable to conventional high-energy-density materials. The amorphization provides an alternative route to the polymerization of nitrogen under moderate conditions.

AB - Metal azides have attracted increasing attention as precursors for synthesizing polymeric nitrogen. In this article, we report the amorphous polymerization of nitrogen by compressing cupric azide. The ab initio molecular dynamics simulations show that crystalline cupric azide transforms into a disordered network composed of singly bonded nitrogen at a hydrostatic pressure of 40 GPa and room temperature. The transformation manifests the formation of a π delocalization along the disordered Cu-N network, thus resulting in a semiconductor–metal transition. The estimated heat of formation of the amorphous polymeric nitrogen system is comparable to conventional high-energy-density materials. The amorphization provides an alternative route to the polymerization of nitrogen under moderate conditions.

KW - ab initio molecular dynamics

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KW - azides

KW - polynitrogen

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Amorphous polymerization of nitrogen in compressed cupric azide

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Keywords

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