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GIANT INTRINSIC CARRIER MOBILITIES IN GRAPHENE AND ITS BILAYER PDF

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Phys Rev Lett. Jan 11;(1) Epub Jan 7. Giant intrinsic carrier mobilities in graphene and its bilayer. Morozov SV(1), Novoselov KS. Giant Intrinsic Carrier Mobilities in Graphene and Its Bilayer. S. V. Morozov,1,2 K. S. Novoselov,1 M. I. Katsnelson,3 F. Schedin,1 D. C. Elias,1. Abstract. We have studied temperature dependences of electron transport in graphene and its bilayer and found extremely low.

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Elias 1J.

You can also email your enquiry to us. Skip to main content. KatsnelsonUniversity of Nijmegen F. Library subscriptions will be modified accordingly. The solid curve is the best fit by using a combination of T and T 5 functions, which intrinnsic here as a guide to the eye.

Bibliographic metadata Type of resource:. EliasUniversity of Manchester John A. Abstract We have studied temperature dependences of electron transport in graphene and its bilayer and found extremely low electron-phonon scattering rates that set the fundamental limit on possible charge carrier mobilities at room itss.

Giant intrinsic carrier mobilities in graphene and its bilayer.

We have studied temperature dependences of electron transport in graphene and its bilayer and found extremely low electron-phonon scattering rates that set the fundamental limit on possible charge carrier mobilities at room temperature. Abstract We have studied temperature dependences of electron transport in graphene and its bilayer and found extremely low electron-phonon scattering rates that set the fundamental limit on possible charge carrier mobilities at room temperature.

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Giant intrinsic carrier mobilities in graphene and its bilayer. University researcher intrineic Konstantin Novoselov’s research staff aand. Jaszczak 4and A. Physical Review Letters, 1. Institutional metadata University researcher s:.

Record metadata Manchester eScholar ID:.

Giant intrinsic carrier mobilities in graphene and its bilayer.

To view the content in amd browser, please download Adobe Reader or, alternately, you may Download the file to your hard drive. Series I Physics Physique Fizika. This arrangement will initially last for two years, up to the end of Related resources Full-text held externally DOI: Figure 3 T -dependent part of resistivity for 4 SLG samples symbols.

Morozov 1,2K. Department of Physics Publications.

Schedin 1D. The experiments were carried out in a field of 0. Weyl fermions are observed in a solid. Katsnelson 3F.

MorozovUniversity of Manchester K. The library chat service will be available from 11am-3pm Monday to Friday excluding Bank Holidays. NovoselovUniversity of Manchester M.

SchedinUniversity of Manchester D. Included in Physics Commons. Abstract We have studied temperature dependences of electron transport in graphene and its bilayer and found extremely low electron-phonon scattering rates that set the fundamental limit on possible charge carrier mobilities at room temperature.

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Recommended Citation Morozov, S. A sharp thresholdlike increase in resistivity observed above similar to K is unexpected but can qualitatively be understood within a model of a rippled graphene sheet in which scattering occurs on intraripple flexural phonons.

Publication Title Physical Review Letters. We have studied temperature dependences of electron transport in graphene and its bilayer and found extremely low electron-phonon scattering rates that set the fundamental limit on possible charge carrier mobilities at room temperature.

Condensed Matter > Mesoscale and Nanoscale Physics

Figure 4 T dependence in bilayer graphene. Publisher’s version ib record: Sign up to receive regular email alerts from Physical Review Letters. GeimUniversity of Manchester.