1
Photonics Electronics Group, Research Institute for Applied Physics & Astronomy (RIAPA), University of Tabriz, Tabriz
2
Department of Chemistry, Ulsan National Institute of Science and Technology, Ulsan, South Korea
Abstract
In this article we will show how different molecules can be identified by the use of graphene 14 nanoribbon. Conductance depend on frontier energy level and spatial orientation of molecules. 15 With this feature, electron transport through molecules that are physically attracted to 16 nanoribbon can be described and calculated. We show that electron transport is unique to each 17 molecule. Because when a molecule attach on graphene nanoribbon sharp dips in T-E graph 18 appears that these dips are different for each molecule. In this paper, physical adsorption of 19 three molecules like ethanol C2H6O, sulfur dioxide SO2 and benzene C6H6 has been 20 studied on graphene nanoribbon.
Kordhaghi,H. , Shojaei,S. and Rezapour,M. R. (2016). Molecular Sensing by the Means of Graphene
Based Field Effect Transistor. (e46485). Nanomeghyas, 3(4), e46485
MLA
Kordhaghi,H. , , Shojaei,S. , and Rezapour,M. R. . "Molecular Sensing by the Means of Graphene
Based Field Effect Transistor" .e46485 , Nanomeghyas, 3, 4, 2016, e46485.
HARVARD
Kordhaghi H., Shojaei S., Rezapour M. R. (2016). 'Molecular Sensing by the Means of Graphene
Based Field Effect Transistor', Nanomeghyas, 3(4), e46485.
CHICAGO
H. Kordhaghi, S. Shojaei and M. R. Rezapour, "Molecular Sensing by the Means of Graphene
Based Field Effect Transistor," Nanomeghyas, 3 4 (2016): e46485,
VANCOUVER
Kordhaghi H., Shojaei S., Rezapour M. R. Molecular Sensing by the Means of Graphene
Based Field Effect Transistor. Nanomeghyas, 2016; 3(4): e46485.
