Structural, electronic, and transport properties of silicane nanoribbons

Silicane ribbons do not suffer from aromatic dependence of the band gap making them a more promising candidate for near-term nanoelectronic application compared to armchair graphene nanoribbons. The structural, electronic, and transport properties of free-standing sp super(3)-hybridized armchair- an...

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Veröffentlicht in:	Physical review. B, Condensed matter and materials physics Condensed matter and materials physics, 2012-11, Vol.86 (20), Article 205323
Hauptverfasser:	Kim, Jiseok, Fischetti, Massimo V., Aboud, Shela
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Sprache:	eng
Schlagworte:	Condensed matter Electron mobility Electronics Graphene Mathematical analysis Nanostructure Ribbons Transport properties
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creator	Kim, Jiseok Fischetti, Massimo V. Aboud, Shela
description	Silicane ribbons do not suffer from aromatic dependence of the band gap making them a more promising candidate for near-term nanoelectronic application compared to armchair graphene nanoribbons. The structural, electronic, and transport properties of free-standing sp super(3)-hybridized armchair- and zigzag-edge silicane nanoribbons have been investigated using ab initio and nonlocal empirical pseudopotential calculations. Under ambient conditions, two-dimensional silicane sheets will spontaneously break into stable one-dimensional ribbons similar to density functional theory studies of graphene ribbons. The calculated low-field electron mobility and ballistic conductance show a strong edge dependence, due to differences in the effective mass and momentum relaxation rates along the two transport directions. The mobility in zigzag-edge ribbons is found to be approximately twenty times higher than in armchair-edge ribbons.
doi_str_mv	10.1103/PhysRevB.86.205323
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B, Condensed matter and materials physics</title><description>Silicane ribbons do not suffer from aromatic dependence of the band gap making them a more promising candidate for near-term nanoelectronic application compared to armchair graphene nanoribbons. The structural, electronic, and transport properties of free-standing sp super(3)-hybridized armchair- and zigzag-edge silicane nanoribbons have been investigated using ab initio and nonlocal empirical pseudopotential calculations. Under ambient conditions, two-dimensional silicane sheets will spontaneously break into stable one-dimensional ribbons similar to density functional theory studies of graphene ribbons. The calculated low-field electron mobility and ballistic conductance show a strong edge dependence, due to differences in the effective mass and momentum relaxation rates along the two transport directions. 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subjects	Condensed matter Electron mobility Electronics Graphene Mathematical analysis Nanostructure Ribbons Transport properties
title	Structural, electronic, and transport properties of silicane nanoribbons
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