Graphene-based biosensor using transport properties

Chowdhury, Rajib; Adhikari, Sondipon; Rees, Paul; Wilks, Steve; Scarpa, F.

doi:10.1103/physrevb.83.045401

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Graphene-based biosensor using transport properties

Rajib Chowdhury, Sondipon Adhikari

, Paul Rees

, Steve Wilks, F. Scarpa

Physical Review B, Volume: 83, Issue: 4

Swansea University Authors: Rajib Chowdhury, Sondipon Adhikari , Paul Rees , Steve Wilks

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DOI (Published version): 10.1103/physrevb.83.045401

Abstract

The potential of graphene nanoribbons (GNR’s) as molecular-scale sensors is investigated by calculating the electronic properties of the ribbon and the organic molecule ensemble. The organic molecule is assumed to be absorbed at the edge of a zigzag GNR. These nanostructures are described using a si...

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Published in:	Physical Review B
ISSN:	1098-0121 1550-235X
Published:	American Physical Society (APS) 2011
Online Access:	Check full text
URI:	https://cronfa.swan.ac.uk/Record/cronfa6327

first_indexed	2013-07-23T11:56:51Z
last_indexed	2023-03-18T03:07:20Z
id	cronfa6327
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spelling	2023-03-17T10:41:22.3435885 v2 6327 2013-01-21 Graphene-based biosensor using transport properties cb6c378733c1f732411646825fb9e289 Rajib Chowdhury Rajib Chowdhury true false 4ea84d67c4e414f5ccbd7593a40f04d3 0000-0003-4181-3457 Sondipon Adhikari Sondipon Adhikari true false 537a2fe031a796a3bde99679ee8c24f5 0000-0002-7715-6914 Paul Rees Paul Rees true false 948a547e27d969b7e192b4620688704d Steve Wilks Steve Wilks true false 2013-01-21 The potential of graphene nanoribbons (GNR’s) as molecular-scale sensors is investigated by calculating the electronic properties of the ribbon and the organic molecule ensemble. The organic molecule is assumed to be absorbed at the edge of a zigzag GNR. These nanostructures are described using a single-band tight-binding Hamiltonian. Their transport spectrum and density of states are calculated using the nonequilibrium Green’s function formalism. The results show a significant suppression of the density of states (DOS), with a distinct response for the molecule. This may be promising for the prospect of GNR-based single-molecule sensors that might depend on the DOS (e.g., devices that respond to changes in either conductance or electroluminescence). Further, we have investigated the effect of doping on the transport properties of the system. The substitutional boron and nitrogen atoms are located at the center and edge of GNR’s. These dopant elements have significant influence on the transport characteristics of the system, particularly doping at the GNR edge. Journal Article Physical Review B 83 4 American Physical Society (APS) 1098-0121 1550-235X 3 1 2011 2011-01-03 10.1103/physrevb.83.045401 http://dx.doi.org/10.1103/physrevb.83.045401 The potential of graphene nanoribbons (GNR’s) as molecular-scale sensors is investigated by calculating the electronic properties of the ribbon and the organic molecule ensemble. The organic molecule is assumed to be absorbed at the edge of a zigzag GNR. These nanostructures are described using a single-band tight-binding Hamiltonian. Their transport spectrum and density of states are calculated using the nonequilibrium Green’s function formalism. The results show a significant suppression of the density of states (DOS), with a distinct response for the molecule. This may be promising for the prospect of GNR-based single-molecule sensors that might depend on the DOS (e.g., devices that respond to changes in either conductance or electroluminescence). Further, we have investigated the effect of doping on the transport properties of the system. The substitutional boron and nitrogen atoms are located at the center and edge of GNR’s. These dopant elements have significant influence on the transport characteristics of the system, particularly doping at the GNR edge.Impact Factor: 3.772 COLLEGE NANME COLLEGE CODE Swansea University 2023-03-17T10:41:22.3435885 2013-01-21T06:02:11.0000000 Faculty of Science and Engineering School of Engineering and Applied Sciences - Biomedical Engineering Rajib Chowdhury 1 Sondipon Adhikari 0000-0003-4181-3457 2 Paul Rees 0000-0002-7715-6914 3 Steve Wilks 4 F. Scarpa 5
title	Graphene-based biosensor using transport properties
spellingShingle	Graphene-based biosensor using transport properties Rajib Chowdhury Sondipon Adhikari Paul Rees Steve Wilks
title_short	Graphene-based biosensor using transport properties
title_full	Graphene-based biosensor using transport properties
title_fullStr	Graphene-based biosensor using transport properties
title_full_unstemmed	Graphene-based biosensor using transport properties
title_sort	Graphene-based biosensor using transport properties
author_id_str_mv	cb6c378733c1f732411646825fb9e289 4ea84d67c4e414f5ccbd7593a40f04d3 537a2fe031a796a3bde99679ee8c24f5 948a547e27d969b7e192b4620688704d
author_id_fullname_str_mv	cb6c378733c1f732411646825fb9e289_*_Rajib Chowdhury 4ea84d67c4e414f5ccbd7593a40f04d3__Sondipon Adhikari 537a2fe031a796a3bde99679ee8c24f5__Paul Rees 948a547e27d969b7e192b4620688704d_*_Steve Wilks
author	Rajib Chowdhury Sondipon Adhikari Paul Rees Steve Wilks
author2	Rajib Chowdhury Sondipon Adhikari Paul Rees Steve Wilks F. Scarpa
format	Journal article
container_title	Physical Review B
container_volume	83
container_issue	4
publishDate	2011
institution	Swansea University
issn	1098-0121 1550-235X
doi_str_mv	10.1103/physrevb.83.045401
publisher	American Physical Society (APS)
college_str	Faculty of Science and Engineering
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hierarchy_top_id	facultyofscienceandengineering
hierarchy_top_title	Faculty of Science and Engineering
hierarchy_parent_id	facultyofscienceandengineering
hierarchy_parent_title	Faculty of Science and Engineering
department_str	School of Engineering and Applied Sciences - Biomedical Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Biomedical Engineering
url	http://dx.doi.org/10.1103/physrevb.83.045401
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description	The potential of graphene nanoribbons (GNR’s) as molecular-scale sensors is investigated by calculating the electronic properties of the ribbon and the organic molecule ensemble. The organic molecule is assumed to be absorbed at the edge of a zigzag GNR. These nanostructures are described using a single-band tight-binding Hamiltonian. Their transport spectrum and density of states are calculated using the nonequilibrium Green’s function formalism. The results show a significant suppression of the density of states (DOS), with a distinct response for the molecule. This may be promising for the prospect of GNR-based single-molecule sensors that might depend on the DOS (e.g., devices that respond to changes in either conductance or electroluminescence). Further, we have investigated the effect of doping on the transport properties of the system. The substitutional boron and nitrogen atoms are located at the center and edge of GNR’s. These dopant elements have significant influence on the transport characteristics of the system, particularly doping at the GNR edge.
published_date	2011-01-03T06:12:18Z
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score	10.890605

Graphene-based biosensor using transport properties

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