Abstract
Graphene nanoribbon (GNR) is a promising alternative to carbon nanotube (CNT) to overcome the chirality challenge as a nanoscale device channel. Due to the one‐dimensional behavior of plane GNR, the carrier statistic study is attractive. Research works have been done on carrier statistic study of GNR especially in the parabolic part of the band structure using Boltzmann approximation (nondegenerate regime). Based on the quantum confinement effect, we have improved the fundamental study in degenerate regime for both the parabolic and nonparabolic parts of GNR band energy. Our results demonstrate that the band energy of GNR near to the minimum band energy is parabolic. In this part of the band structure, the Fermi‐Dirac integrals are sufficient for the carrier concentration study. The Fermi energy showed the temperature‐dependent behavior similar to any other one‐dimensional device in nondegenerate regime. However in the degenerate regime, the normalized Fermi energy with respect to the band edge is a function of carrier concentration. The numerical solution of Fermi‐Dirac integrals for nonparabolic region, which is away from the minimum energy band structure of GNR, is also presented.
Highlights
Single layer of graphite which is known as graphene has been discovered as a material with attractive lowdimensional physics, and possible applications in electronics [1,2,3,4,5,6]
Armchair and zigzag Graphene nanoribbon (GNR) show metallic or semiconducting electronic properties depending on the number of dimer lines, N which gives the width of the nanoribbon as depicted in Figures 1 and 2
GNR Fermi energy is a function of temperature that is independent of the carrier concentration in the nondegenerate regime
Summary
Single layer of graphite which is known as graphene has been discovered as a material with attractive lowdimensional physics, and possible applications in electronics [1,2,3,4,5,6]. Band-gap opening is expected by patterning narrow ribbons [7, 8] from Graphene which can be achieved by chemical means [9]. This Graphene nanoribbon (GNR) with quasi-one-dimensional structures and narrow widths (
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