High frequency conductivity in carbon nanotubes
We report on theoretical analysis of high frequency conductivity in carbon nanotubes. Using the kinetic equation with constant relaxation time, an analytical expression for the complex conductivity is obtained. The real part of the complex conductivity is initially negative at zero frequency and bec...
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AIP Publishing LLC
2012-12-01
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| Series: | AIP Advances |
| Online Access: | http://dx.doi.org/10.1063/1.4771677 |
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doaj-09c8b9b5e39440ac9d277cc9654a0d7d2020-11-24T21:37:56ZengAIP Publishing LLCAIP Advances2158-32262012-12-0124042178042178-510.1063/1.4771677079204ADVHigh frequency conductivity in carbon nanotubesS. S. Abukari0S. Y. Mensah1N. G. Mensah2K. A. Adu3M. Rabiu4A. Twum5Department of Physics, Laser and Fiber Optics Center, University of Cape Coast, Cape Coast, GhanaDepartment of Physics, Laser and Fiber Optics Center, University of Cape Coast, Cape Coast, GhanaDepartment of Mathematics, University of Cape Coast, Cape Coast, GhanaDepartment of Physics, The Pennsylvania State University Altoona College, Altoona, Pennsylvania 16601, USA and Materials Research Institute, The Pennsylvania State University, University Park, Pennsylvania 16802, USADepartment of Applied Physics, Faculty of Applied Sciences, University for Development Studies, Navrongo Campus, GhanaDepartment of Physics, Laser and Fiber Optics Center, University of Cape Coast, Cape Coast, GhanaWe report on theoretical analysis of high frequency conductivity in carbon nanotubes. Using the kinetic equation with constant relaxation time, an analytical expression for the complex conductivity is obtained. The real part of the complex conductivity is initially negative at zero frequency and become more negative with increasing frequency, until it reaches a resonance minimum at ω ∼ ωB for metallic zigzag CNs and ω < ωB for armchair CNs. This resonance enhancement is indicative for terahertz gain without the formation of current instabilities induced by negative dc conductivity. We noted that due to the high density of states of conduction electrons in metallic zigzag carbon nanotubes and the specific dispersion law inherent in hexagonal crystalline structure result in a uniquely high frequency conductivity than the corresponding values for metallic armchair carbon nanotubes. We suggest that this phenomenon can be used to suppress current instabilities that are normally associated with a negative dc differential conductivity.http://dx.doi.org/10.1063/1.4771677 |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
S. S. Abukari S. Y. Mensah N. G. Mensah K. A. Adu M. Rabiu A. Twum |
| spellingShingle |
S. S. Abukari S. Y. Mensah N. G. Mensah K. A. Adu M. Rabiu A. Twum High frequency conductivity in carbon nanotubes AIP Advances |
| author_facet |
S. S. Abukari S. Y. Mensah N. G. Mensah K. A. Adu M. Rabiu A. Twum |
| author_sort |
S. S. Abukari |
| title |
High frequency conductivity in carbon nanotubes |
| title_short |
High frequency conductivity in carbon nanotubes |
| title_full |
High frequency conductivity in carbon nanotubes |
| title_fullStr |
High frequency conductivity in carbon nanotubes |
| title_full_unstemmed |
High frequency conductivity in carbon nanotubes |
| title_sort |
high frequency conductivity in carbon nanotubes |
| publisher |
AIP Publishing LLC |
| series |
AIP Advances |
| issn |
2158-3226 |
| publishDate |
2012-12-01 |
| description |
We report on theoretical analysis of high frequency conductivity in carbon nanotubes. Using the kinetic equation with constant relaxation time, an analytical expression for the complex conductivity is obtained. The real part of the complex conductivity is initially negative at zero frequency and become more negative with increasing frequency, until it reaches a resonance minimum at ω ∼ ωB for metallic zigzag CNs and ω < ωB for armchair CNs. This resonance enhancement is indicative for terahertz gain without the formation of current instabilities induced by negative dc conductivity. We noted that due to the high density of states of conduction electrons in metallic zigzag carbon nanotubes and the specific dispersion law inherent in hexagonal crystalline structure result in a uniquely high frequency conductivity than the corresponding values for metallic armchair carbon nanotubes. We suggest that this phenomenon can be used to suppress current instabilities that are normally associated with a negative dc differential conductivity. |
| url |
http://dx.doi.org/10.1063/1.4771677 |
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