|Intrinsic and Extrinsic Limits of Charge Carrier Mobility in Graphene |
Physics and Astronomy
|Michael Fuhrer, University of Maryland College Park|
1:30 PM, Serin E385
Graphene, a single atom-thick sheet of graphite, is a zero-gap semiconductor with an unusual linear dispersion relation (analogous to the Dirac equation for massless relativistic particles) and a density of states that vanishes at a singular point. Graphene is
an exciting new condensed matter system, both for the opportunity to observe the physics associated with massless Dirac Fermions in the laboratory, and because of materials parameters which make it attractive for technological applications. However, in the few
years since the experimental realization of graphene, progress toward cleaner (higher mobility) samples has largely stalled. I will discuss experiments performed on atomically-clean graphene on SiO2 in ultra-high vacuum to determine the intrinsic and extrinsic limits of mobility in graphene[2,3], which point out both the promise of the
material as well as the technological challenges that lie ahead in realizing better graphene samples. Intrinsic scattering by the acoustic phonons of graphene limits the room-temperature mobility to 2 x 105 cm2/Vs at a carrier density of 1012 cm-2, higher than any
known material. However, extrinsic scattering due to charged impurities in the substrate and substrate polar optical phonons currently impose much more severe limits on the mobility, pointing out the importance of substrate engineering for improving graphene devices.
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 "Charged Impurity Scattering in Graphene," J. H. Chen, C. Jang, M. S. Fuhrer, E. D. Williams, and M. Ishigami, arXiv:0708.2408.
 "Intrinsic and Extrinsic Performance Limits of Graphene Devices on SiO2," J. H. Chen, C. Jang, S. Xiao, M. Ishigami, M. S. Fuhrer, arXiv:0711.3646.
 "Printed Graphene Circuits," Jian-Hao Chen, Masa Ishigami, Chaun Jang, Daniel R. Hines, Michael S. Fuhrer, and Ellen D. Williams, Advanced Materials 19, 3623 (2007).