Modelling effective charge density in graphene-gased DNA sensor

Due to its unique properties, including high conductivity, large surface area and significant mechanical strength, graphene has attracted a great deal of attention among researchers in physics, biology, nanoelectronics and nanotechnology fields, especially over the past few years. A fundamental unde...

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Main Authors: Karimi, H., Rahmani, R., Ahmadi, M. T., Ismail, R.
Format: Article
Published: American Scientific Publishers 2016
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Online Access:http://eprints.utm.my/id/eprint/70002/
http://dx.doi.org/10.1166/sam.2016.2679
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Institution: Universiti Teknologi Malaysia
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spelling my.utm.700022017-11-20T08:52:13Z http://eprints.utm.my/id/eprint/70002/ Modelling effective charge density in graphene-gased DNA sensor Karimi, H. Rahmani, R. Ahmadi, M. T. Ismail, R. T Technology (General) Due to its unique properties, including high conductivity, large surface area and significant mechanical strength, graphene has attracted a great deal of attention among researchers in physics, biology, nanoelectronics and nanotechnology fields, especially over the past few years. A fundamental understanding of the DNA-hybridization detection mechanism and technical prediction and optimization of many graphene-based DNA sensors requires extensive modeling and simulation of devices. Although there have been numerous experimental studies in this field, the lack of analytical models is felt deeply. In this work, to start with modelling, a liquid field effect transistor-based structure is employed as a platform, and graphene charge density variation based on the Poisson-Boltzman equations are studied under the impact induced by the adsorption of different values of DNA concentration on its surface. The effect of DNA molecules concentration and surface charge density of ssDNA and dsDNA before and after hybridization are considered in the calculation of the analytical model. The obtained current-voltage characteristics of the proposed model are compared with available experimental data existing, and a good agreement is found. For all the concentrations considered in this work, the proposed model can track experimental curves documented by other authors, with acceptable accuracy. American Scientific Publishers 2016 Article PeerReviewed Karimi, H. and Rahmani, R. and Ahmadi, M. T. and Ismail, R. (2016) Modelling effective charge density in graphene-gased DNA sensor. Science of Advanced Materials, 8 (6). pp. 1187-1194. ISSN 1947-2935 http://dx.doi.org/10.1166/sam.2016.2679 DOI:10.1166/sam.2016.2679
institution Universiti Teknologi Malaysia
building UTM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Malaysia
content_source UTM Institutional Repository
url_provider http://eprints.utm.my/
topic T Technology (General)
spellingShingle T Technology (General)
Karimi, H.
Rahmani, R.
Ahmadi, M. T.
Ismail, R.
Modelling effective charge density in graphene-gased DNA sensor
description Due to its unique properties, including high conductivity, large surface area and significant mechanical strength, graphene has attracted a great deal of attention among researchers in physics, biology, nanoelectronics and nanotechnology fields, especially over the past few years. A fundamental understanding of the DNA-hybridization detection mechanism and technical prediction and optimization of many graphene-based DNA sensors requires extensive modeling and simulation of devices. Although there have been numerous experimental studies in this field, the lack of analytical models is felt deeply. In this work, to start with modelling, a liquid field effect transistor-based structure is employed as a platform, and graphene charge density variation based on the Poisson-Boltzman equations are studied under the impact induced by the adsorption of different values of DNA concentration on its surface. The effect of DNA molecules concentration and surface charge density of ssDNA and dsDNA before and after hybridization are considered in the calculation of the analytical model. The obtained current-voltage characteristics of the proposed model are compared with available experimental data existing, and a good agreement is found. For all the concentrations considered in this work, the proposed model can track experimental curves documented by other authors, with acceptable accuracy.
format Article
author Karimi, H.
Rahmani, R.
Ahmadi, M. T.
Ismail, R.
author_facet Karimi, H.
Rahmani, R.
Ahmadi, M. T.
Ismail, R.
author_sort Karimi, H.
title Modelling effective charge density in graphene-gased DNA sensor
title_short Modelling effective charge density in graphene-gased DNA sensor
title_full Modelling effective charge density in graphene-gased DNA sensor
title_fullStr Modelling effective charge density in graphene-gased DNA sensor
title_full_unstemmed Modelling effective charge density in graphene-gased DNA sensor
title_sort modelling effective charge density in graphene-gased dna sensor
publisher American Scientific Publishers
publishDate 2016
url http://eprints.utm.my/id/eprint/70002/
http://dx.doi.org/10.1166/sam.2016.2679
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