TiO2 nanowires as a wide bandgap dirac material: A numerical study of impurity scattering and Anderson disorder

Gabriele Penazzi; Peter Deák; Bálint Aradi; Tim Wehling; Alessio Gagliardi; Huynh Anh Huy; Binghai Yan; Thomas Frauenheim

doi:10.1557/opl.2014.150

TiO₂ nanowires as a wide bandgap dirac material: A numerical study of impurity scattering and Anderson disorder

Gabriele Penazzi, Peter Deák, Bálint Aradi, Tim Wehling, Alessio Gagliardi, Huynh Anh Huy, Binghai Yan, Thomas Frauenheim

Physics

Research output: Contribution to journal › Conference article › peer-review

Abstract

Dirac materials are characterized by exceptional mobility, orders of magnitude higher than any semiconductor, due to the massless pseudorelativistic nature of the Dirac fermions. These systems being semimetallic, the lack of a genuine band-gap poses a serious limitation to their possible applications in electronics. We recently demonstrated that thin TiO2 nanowires can exhibit 1D Dirac states similar to metallic carbon nanotubes, with the crucial difference that these states lie inside the conduction band in proximity of a wide band gap. We analyze the robustness of the Dirac states respect to an Anderson disorder model and substitutional impurity and compare to different one dimensional systems. The results suggest that thin anatase TiO2 nanowires can be a promising candidate material for switching devices.

Original language	English (US)
Journal	Materials Research Society Symposium Proceedings
Volume	1659
DOIs	https://doi.org/10.1557/opl.2014.150
State	Published - 2014
Event	2013 MRS Fall Meeting - Boston, MA, United States Duration: Dec 1 2013 → Dec 6 2013

All Science Journal Classification (ASJC) codes

General Materials Science
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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title = "TiO2 nanowires as a wide bandgap dirac material: A numerical study of impurity scattering and Anderson disorder",

abstract = "Dirac materials are characterized by exceptional mobility, orders of magnitude higher than any semiconductor, due to the massless pseudorelativistic nature of the Dirac fermions. These systems being semimetallic, the lack of a genuine band-gap poses a serious limitation to their possible applications in electronics. We recently demonstrated that thin TiO2 nanowires can exhibit 1D Dirac states similar to metallic carbon nanotubes, with the crucial difference that these states lie inside the conduction band in proximity of a wide band gap. We analyze the robustness of the Dirac states respect to an Anderson disorder model and substitutional impurity and compare to different one dimensional systems. The results suggest that thin anatase TiO2 nanowires can be a promising candidate material for switching devices.",

author = "Gabriele Penazzi and Peter De{\'a}k and B{\'a}lint Aradi and Tim Wehling and Alessio Gagliardi and Huy, {Huynh Anh} and Binghai Yan and Thomas Frauenheim",

year = "2014",

doi = "10.1557/opl.2014.150",

language = "English (US)",

volume = "1659",

journal = "Materials Research Society Symposium Proceedings",

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publisher = "Materials Research Society",

note = "2013 MRS Fall Meeting ; Conference date: 01-12-2013 Through 06-12-2013",

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T1 - TiO2 nanowires as a wide bandgap dirac material

T2 - 2013 MRS Fall Meeting

AU - Penazzi, Gabriele

AU - Deák, Peter

AU - Aradi, Bálint

AU - Wehling, Tim

AU - Gagliardi, Alessio

AU - Huy, Huynh Anh

AU - Yan, Binghai

AU - Frauenheim, Thomas

PY - 2014

Y1 - 2014

N2 - Dirac materials are characterized by exceptional mobility, orders of magnitude higher than any semiconductor, due to the massless pseudorelativistic nature of the Dirac fermions. These systems being semimetallic, the lack of a genuine band-gap poses a serious limitation to their possible applications in electronics. We recently demonstrated that thin TiO2 nanowires can exhibit 1D Dirac states similar to metallic carbon nanotubes, with the crucial difference that these states lie inside the conduction band in proximity of a wide band gap. We analyze the robustness of the Dirac states respect to an Anderson disorder model and substitutional impurity and compare to different one dimensional systems. The results suggest that thin anatase TiO2 nanowires can be a promising candidate material for switching devices.

AB - Dirac materials are characterized by exceptional mobility, orders of magnitude higher than any semiconductor, due to the massless pseudorelativistic nature of the Dirac fermions. These systems being semimetallic, the lack of a genuine band-gap poses a serious limitation to their possible applications in electronics. We recently demonstrated that thin TiO2 nanowires can exhibit 1D Dirac states similar to metallic carbon nanotubes, with the crucial difference that these states lie inside the conduction band in proximity of a wide band gap. We analyze the robustness of the Dirac states respect to an Anderson disorder model and substitutional impurity and compare to different one dimensional systems. The results suggest that thin anatase TiO2 nanowires can be a promising candidate material for switching devices.

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TiO₂ nanowires as a wide bandgap dirac material: A numerical study of impurity scattering and Anderson disorder

Abstract

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