Charged-impurity scattering in graphene

Chen, Jianhao; Jang, Chaun; Adam, Shaffique; Fuhrer, Michael S.; Williams, Ellen D.; Ishigami, Masa

doi:10.1038/nphys935

Cited by 1,400 publications

(1,471 citation statements)

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“…An insertion loss of 5% is close to our experimental observation while being a conservative estimate of the graphene minimum AC conductivity 19,36 , based on the experimentally measured DC conductivity 37 . This means that extremely low intrinsic signal attenuation can be achieved in graphene terahertz modulators: < 0.2 dB per single-layer graphene.…”

Section: Static Characteristicssupporting

confidence: 84%

Broadband graphene terahertz modulators enabled by intraband transitions

et al. 2012

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Terahertz technology promises myriad applications including imaging, spectroscopy and communications. However, one major bottleneck at present for advancing this field is the lack of efficient devices to manipulate the terahertz electromagnetic waves. Here we demonstrate that exceptionally efficient broadband modulation of terahertz waves at room temperature can be realized using graphene with extremely low intrinsic signal attenuation. We experimentally achieved more than 2.5 times superior modulation than prior broadband intensity modulators, which is also the first demonstrated graphene-based device enabled solely by intraband transitions. The unique advantages of graphene in comparison to conventional semiconductors are the ease of integration and the extraordinary transport properties of holes, which are as good as those of electrons owing to the symmetric conical band structure of graphene. Given recent progress in graphene-based terahertz emitters and detectors, graphene may offer some interesting solutions for terahertz technologies.

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Section: Static Characteristicssupporting

confidence: 84%

Broadband graphene terahertz modulators enabled by intraband transitions

et al. 2012

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“…However, distribution of the metal atoms on the graphene surface is usually inhomogeneous, and the resulting charged impurities cause significant reduction of the carrier mobility. 14 The single, open-shell NO 2 molecule is found to be a strong acceptor, whereas its equilibrium gaseous state N 2 O 4 acts as a weak dopant and does not result in any significant doping effect. 15 Boron or nitrogen substitutional doping is also not reliable and always induces defects that destroy the promising electronic property of graphene.…”

mentioning

confidence: 95%

“…TCNE molecules are more advantageous compared to alkali atoms because the intermolecular repulsive interaction leads to uniform distribution of the molecules at increasing coverage. 14 The P-N junction is a basic unit in integrated circuits, and it is desirerable to fabricate P-N junctions on a graphene layer for graphene-based electronic devices. An organic molecule may be useful for achieving this goal.…”

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confidence: 99%

Tuning the Electronic Structure of Graphene by an Organic Molecule

et al. 2008

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The electronic structure of an electron-acceptor molecule, tetracyanoethylene (TCNE), on graphene was investigated using the first-principles method based on density functional theory. It was theoretically demonstrated that a p-type graphene can be obtained via charge transfer between an organic molecule and graphene. Both the carrier concentration and band gap at the Dirac point can be controlled by coverage of organic molecules. The spin split and partially filled π* orbitals of the TCNE anion radical induce spin density in the graphene layer. Surface modification of graphene by organic molecules could be a simple and effective method to control the electronic structure of graphene over a wide range.

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“…The sheet resistance is high, and the Dirac neutrality point is not visible in the explored backgate voltage range. This is due to the presence of residuals and impurities on the surface of graphene, which act as scatterers and degrade the conductance [43,44]. In order to improve the electrical properties of graphene, we performed current annealing [45], that is the application of a controlled large current to recover its electrical properties.…”

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confidence: 99%