Nanoscale stabilization of zintl compounds: 1D ionic Li-P double helix confined inside a carbon nanotube

Alexander S. Ivanov; Tapas Kar; Alexander I. Boldyrev

doi:10.1039/c5nr07713c

Nanoscale stabilization of zintl compounds: 1D ionic Li-P double helix confined inside a carbon nanotube

Alexander S. Ivanov, Tapas Kar, Alexander I. Boldyrev

Nanomaterials Chemistry Group

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

13 Scopus citations

Abstract

One-dimensional (1D) ionic nanowires are extremely rare materials due to the difficulty in stabilizing 1D chains of ions under ambient conditions. We demonstrate here a theoretical prediction of a novel hybrid material, a nanotube encapsulated 1D ionic lithium monophosphide (LiP) chain, featuring a unique double-helix structure, which is very unusual in inorganic chemistry. This nanocomposite has been investigated with density functional theory, including molecular dynamics simulations and electronic structure calculations. We find that the formation of the LiP double-helical nanowire is facilitated by strong interactions between LiP and CNTs resulting in a charge transfer. This work suggests that nanostructured confinement may be used to stabilize other polyphosphide 1D chains, thus opening new ways to study the chemistry of zintl compounds at the nanoscale.

Original language	English
Pages (from-to)	3454-3460
Number of pages	7
Journal	Nanoscale
Volume	8
Issue number	6
DOIs	https://doi.org/10.1039/c5nr07713c
State	Published - Feb 14 2016

Funding

This work was supported by the National Science Foundation (CHE-1361413 to A. I. B.). Computer, storage and other resources from the Division of Research Computing in the Office of Research and Graduate Studies at Utah State University and the Center for High Performance Computing at the University of Utah are gratefully acknowledged.

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title = "Nanoscale stabilization of zintl compounds: 1D ionic Li-P double helix confined inside a carbon nanotube",

abstract = "One-dimensional (1D) ionic nanowires are extremely rare materials due to the difficulty in stabilizing 1D chains of ions under ambient conditions. We demonstrate here a theoretical prediction of a novel hybrid material, a nanotube encapsulated 1D ionic lithium monophosphide (LiP) chain, featuring a unique double-helix structure, which is very unusual in inorganic chemistry. This nanocomposite has been investigated with density functional theory, including molecular dynamics simulations and electronic structure calculations. We find that the formation of the LiP double-helical nanowire is facilitated by strong interactions between LiP and CNTs resulting in a charge transfer. This work suggests that nanostructured confinement may be used to stabilize other polyphosphide 1D chains, thus opening new ways to study the chemistry of zintl compounds at the nanoscale.",

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AU - Boldyrev, Alexander I.

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Y1 - 2016/2/14

N2 - One-dimensional (1D) ionic nanowires are extremely rare materials due to the difficulty in stabilizing 1D chains of ions under ambient conditions. We demonstrate here a theoretical prediction of a novel hybrid material, a nanotube encapsulated 1D ionic lithium monophosphide (LiP) chain, featuring a unique double-helix structure, which is very unusual in inorganic chemistry. This nanocomposite has been investigated with density functional theory, including molecular dynamics simulations and electronic structure calculations. We find that the formation of the LiP double-helical nanowire is facilitated by strong interactions between LiP and CNTs resulting in a charge transfer. This work suggests that nanostructured confinement may be used to stabilize other polyphosphide 1D chains, thus opening new ways to study the chemistry of zintl compounds at the nanoscale.

AB - One-dimensional (1D) ionic nanowires are extremely rare materials due to the difficulty in stabilizing 1D chains of ions under ambient conditions. We demonstrate here a theoretical prediction of a novel hybrid material, a nanotube encapsulated 1D ionic lithium monophosphide (LiP) chain, featuring a unique double-helix structure, which is very unusual in inorganic chemistry. This nanocomposite has been investigated with density functional theory, including molecular dynamics simulations and electronic structure calculations. We find that the formation of the LiP double-helical nanowire is facilitated by strong interactions between LiP and CNTs resulting in a charge transfer. This work suggests that nanostructured confinement may be used to stabilize other polyphosphide 1D chains, thus opening new ways to study the chemistry of zintl compounds at the nanoscale.

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Nanoscale stabilization of zintl compounds: 1D ionic Li-P double helix confined inside a carbon nanotube

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