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JOURNALS // Pis'ma v Zhurnal Èksperimental'noi i Teoreticheskoi Fiziki // Archive

Pis'ma v Zh. Èksper. Teoret. Fiz., 2008 Volume 88, Issue 5, Pages 370–373 (Mi jetpl217)

This article is cited in 24 papers

CONDENSED MATTER

Effect of Coulomb scattering on graphene conductivity

V. Vyurkova, V. Ryzhiibc

a Institute of Physics and Technology RAS, 117218 Moscow, Russia
b University of Aizu, Aizu-Wakamatsu 965-8580
c Japan Science and Technology Agency, CREST, 107-0075 Tokyo, Japan

Abstract: The effect of Coulomb scattering on graphene conductivity in field effect transistor structures is discussed. Inter-particle scattering (electron-electron, hole-hole, and electron-hole) and scattering on charged defects are taken into account in a wide range of gate voltages. It is shown that an intrinsic conductivity of graphene (purely ambipolar system where both electron and hole densities exactly coincide) is defined by strong electron-hole scattering. It has a universal value independent of temperature. We give an explicit derivation based on scaling theory. When there is even a small discrepancy in electron and hole densities caused by applied gate voltage the conductivity is determined by both strong electron-hole scattering and weak external scattering: on defects or phonons. We suggest that a density of charged defects (occupancy of defects) depends on Fermi energy to explain a sub-linear dependence of conductivity on a fairly high gate voltage observed in experiments. We also eliminate contradictions between experimental data obtained in deposited and suspended graphene structures regarding graphene conductivity.

PACS: 73.63.-b, 81.05.Uw

Received: 03.07.2008

Language: English


 English version:
Journal of Experimental and Theoretical Physics Letters, 2008, 88:5, 322–325

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