Vacancy Induced Energy Band Gap Changes of Semiconducting Zigzag Single Walled Carbon Nanotubes

In this work, we have examined how the multivacancy defects induced in the horizontal direction change the energetics and the electronic structure of semiconducting Single-Walled Carbon Nanotubes (SWCNTs). The electronic structure of SWCNTs is computed for each deformed configuration by means of rea...

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Published in:Advances in electrical and computer engineering 2017-01, Vol.17 (3), p.11-18
Main Authors: DERELI, G., EYECIOGLU, O., MISIRLIOGLU, B. S.
Format: Article
Language:English
Subjects:
Carbon
Classification
Computer simulation
Defects
Divacancies
electronic properties
Electronic structure
Energy
energy band gap
Energy bands
Energy gap
Horizontal orientation
Investigations
Mechanical properties
Molecular dynamics
order N tight-binding molecular dynamics
Researchers
Simulation
Single wall carbon nanotubes
single-walled carbon nanotubes
Vacancies
vacancy
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EYECIOGLU, O.
MISIRLIOGLU, B. S.
description In this work, we have examined how the multivacancy defects induced in the horizontal direction change the energetics and the electronic structure of semiconducting Single-Walled Carbon Nanotubes (SWCNTs). The electronic structure of SWCNTs is computed for each deformed configuration by means of real space, Order(N) Tight Binding Molecular Dynamic (O(N) TBMD) simulations. Energy band gap is obtained in real space through the behavior of electronic density of states (eDOS) near the Fermi level. Vacancies can effectively change the energetics and hence the electronic structure of SWCNTs. In this study, we choose three different kinds of semiconducting zigzag SWCNTs and determine the band gap modifications. We have selected (12,0), (13,0) and (14,0) zigzag SWCNTs according to n (mod 3) = 0, n (mod 3) = 1 and n (mod 3) = 2 classification. (12,0) SwCnT is metallic in its pristine state. The application of vacancies opens the electronic band gap and it goes up to 0.13 eV for a di-vacancy defected tube. On the other hand (13,0) and (14,0) SWCNTs are semiconductors with energy band gap values of 0.44 eV and 0.55 eV in their pristine state, respectively. Their energy band gap values decrease to 0.07 eV and 0.09 eV when monovacancy defects are induced in their horizontal directions. Then the di-vacancy defects open the band gap again. So in both cases, the semiconducting-metallic - semiconducting transitions occur. It is also shown that the band gap modification exhibits irreversible characteristics, which means that band gap values of the nanotubes do not reach their pristine values with increasing number of vacancies.
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The application of vacancies opens the electronic band gap and it goes up to 0.13 eV for a di-vacancy defected tube. On the other hand (13,0) and (14,0) SWCNTs are semiconductors with energy band gap values of 0.44 eV and 0.55 eV in their pristine state, respectively. Their energy band gap values decrease to 0.07 eV and 0.09 eV when monovacancy defects are induced in their horizontal directions. Then the di-vacancy defects open the band gap again. So in both cases, the semiconducting-metallic - semiconducting transitions occur. 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S.</creatorcontrib><title>Vacancy Induced Energy Band Gap Changes of Semiconducting Zigzag Single Walled Carbon Nanotubes</title><title>Advances in electrical and computer engineering</title><description>In this work, we have examined how the multivacancy defects induced in the horizontal direction change the energetics and the electronic structure of semiconducting Single-Walled Carbon Nanotubes (SWCNTs). The electronic structure of SWCNTs is computed for each deformed configuration by means of real space, Order(N) Tight Binding Molecular Dynamic (O(N) TBMD) simulations. Energy band gap is obtained in real space through the behavior of electronic density of states (eDOS) near the Fermi level. Vacancies can effectively change the energetics and hence the electronic structure of SWCNTs. In this study, we choose three different kinds of semiconducting zigzag SWCNTs and determine the band gap modifications. 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subjects Carbon
Classification
Computer simulation
Defects
Divacancies
electronic properties
Electronic structure
Energy
energy band gap
Energy bands
Energy gap
Horizontal orientation
Investigations
Mechanical properties
Molecular dynamics
order N tight-binding molecular dynamics
Researchers
Simulation
Single wall carbon nanotubes
single-walled carbon nanotubes
Vacancies
vacancy
title Vacancy Induced Energy Band Gap Changes of Semiconducting Zigzag Single Walled Carbon Nanotubes
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