Smallest Nanotube: Breaking the Symmetry of sp3 Bonds in Tubular Geometries

Dragan Stojkovic; Peihong Zhang; Vincent H. Crespi

doi:10.1103/PhysRevLett.87.125502

Smallest Nanotube: Breaking the Symmetry of sp₃ Bonds in Tubular Geometries

Dragan Stojkovic, Peihong Zhang, Vincent H. Crespi

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104 Scopus citations

Abstract

We describe how sp² carbon, threefold coordinated by other carbons, can be replaced by sp3 carbon, also threefold carbon coordinated, to produce extremely small-diameter (∼0.4nm) carbon nanowires with only minimal bond-angle distortion. Under a naming convention analogous to that for ordinary carbon nanotubes, the smallest sp3 tubes have wrapping indices (3,0) and (2,2). These systems have large band gaps and a stiffness larger even than that of traditional sp²-bonded carbon nanotubes. They therefore form the stiffest one-dimensional systems known.

Original language	English (US)
Journal	Physical review letters
Volume	87
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevLett.87.125502
State	Published - 2001

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.87.125502

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abstract = "We describe how sp2 carbon, threefold coordinated by other carbons, can be replaced by sp3 carbon, also threefold carbon coordinated, to produce extremely small-diameter (∼0.4nm) carbon nanowires with only minimal bond-angle distortion. Under a naming convention analogous to that for ordinary carbon nanotubes, the smallest sp3 tubes have wrapping indices (3,0) and (2,2). These systems have large band gaps and a stiffness larger even than that of traditional sp2-bonded carbon nanotubes. They therefore form the stiffest one-dimensional systems known.",

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AB - We describe how sp2 carbon, threefold coordinated by other carbons, can be replaced by sp3 carbon, also threefold carbon coordinated, to produce extremely small-diameter (∼0.4nm) carbon nanowires with only minimal bond-angle distortion. Under a naming convention analogous to that for ordinary carbon nanotubes, the smallest sp3 tubes have wrapping indices (3,0) and (2,2). These systems have large band gaps and a stiffness larger even than that of traditional sp2-bonded carbon nanotubes. They therefore form the stiffest one-dimensional systems known.

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Smallest Nanotube: Breaking the Symmetry of sp₃ Bonds in Tubular Geometries

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All Science Journal Classification (ASJC) codes

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