George S. Kliros
Published 2011-05-29Version 1
Graphene nanostructures exhibit an intrinsic advantage in relation to the gate delay in three-terminal devices and provide additional benefits when operate in the quantum capacitance limit. In this paper, we developed a simple model that captures the Fermi energy and temperature dependence of the quantum capacitance for monolayer and bilayer graphene devices. Quantum capacitance is calculated from the broadened density of states taking into account electron-hole puddles and possible finite lifetime of electronic states through a Gaussian broadening distribution. The obtained results are in agreement with many features recently observed in quantum capacitance measurements on both gated monolayer and bilayer graphene devices. The temperature dependence of the minimum quantum capacitance around the charge neutrality point is also investigated.
Comments: 7 pages, 4 figures, to appear in Rom. J. Inf. Sci. Technol. Vol.11 (2011)
Journal: Rom. J. Inf. Sci. Technol. Vol.10, no.3, pp.332-341 (2010)
Temperature dependence of ambipolar diffusion in silicon-on-insulator
Micro-SQUID technique for studying the temperature dependence of switching fields of single nanoparticles
Hall field-induced magneto-oscillations near charge neutrality point in graphene
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