Space-time dispersion of graphene conductivity

Falkovsky, L. A.; Varlamov, A. A.

doi:10.1140/epjb/e2007-00142-3

Cited by 746 publications

(669 citation statements)

References 25 publications

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“…It consists of considering the ballistic evolution of the current density in time after a sudden or gradual switching on of the electric …eld. The result within linear response is that the current settles very fast, on the microscopic time scale of t =~= ' 0:24 f s ( being the hopping energy), on the value of J = 2 E. The value is identical to the one obtained (at nonzero temperatures) for the AC conductivity [12]. The two contributions, polarization and attenuation are comparable in strength and combine to produce a constant total current.…”

Section: Introductionsupporting

confidence: 54%

Signature of Schwinger's pair creation rate via radiation generated in graphene by strong electric current

Rosenstein

Lewkowicz

Kao

2012

J. Phys.: Conf. Ser.

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Electron -hole pairs are copuously created by an applied electric …eld near the Dirac point in graphene or similar 2D electronic systems. It was shown recently that for su¢ ciently large electric …elds E and ballistic times the I-V characteristics become strongly nonlinear due to Schwinger's pair creation rate, proportional to E 3=2 . Since there is no energy gap the radiation from the pairs' annihilation is enhanced. The spectrum of radiation is calculated and exhibits a maximum at ! = p eEvg=~. The angular and polarization dependence of the emitted photons with respect to the graphene sheet is quite distinctive. For very large currents the recombination rate becomes so large that it leads to the second Ohmic regime due to radiation friction.

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Section: Introductionsupporting

confidence: 54%

Signature of Schwinger's pair creation rate via radiation generated in graphene by strong electric current

Rosenstein

Lewkowicz

Kao

2012

J. Phys.: Conf. Ser.

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“…The theoretical spectra were calculated by numerically solving classical electromagnetic equations using finite element method. 1,7 The background doping observed in our samples has been shown previously to be mainly caused by the FeCl etchant that is used to remove the copper foil from the as-grown CVD graphene, 7 although atmospheric impurities, and charge traps in the substrate can also play a role. 8,9 Interband transition measurements and E F fittings performed on bare graphene areas showed a similar gate vs. carrier density dependence to the patterned graphene areas, as was also observed in previous works.…”

Section: Determination Of Carrier Density Of Graphene Sheetmentioning

confidence: 52%

“…The sheet conductivity of graphene σ(ω) is evaluated within the local phase approximation. 1 Here, the temperature ܶ is set as 300K. The carrier scattering rate Γ takes into account scattering by impurities with the carrier mobility of 500cm 2 /Vs, and by optical phonons estimated from theoretically obtained self-energy.…”

Section: Electromagnetic Simulationsmentioning

confidence: 99%

Hybrid Surface-Phonon-Plasmon Polariton Modes in Graphene/Monolayer h-BN Heterostructures

Brar¹,

Jang

Sherrott³

et al. 2014

Nano Lett.

321

282

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Infrared transmission measurements reveal the hybridization of graphene plasmons and the phonons in a monolayer hexagonal boron nitride (h-BN) sheet. Frequencywavevector dispersion relations of the electromagnetically coupled graphene plasmon/h-BN phonon modes are derived from measurement of nanoresonators with widths varying from 30 to 300 nm. It is shown that the graphene plasmon mode is split into two distinct optical modes that display an anticrossing behavior near the energy of the h-BN optical phonon at 1370 cm −1 . We explain this behavior as a classical electromagnetic strong-coupling with the highly confined near fields of the graphene plasmons allowing for hybridization with the phonons of the atomically thin h-BN layer to create two clearly separated new surface-phonon-plasmon-polariton (SPPP) modes.

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“…For noble metals, we obtain these parameters by fitting the measured dielectric function of the material [106] to the expression (ω) = 1 − ω 2 bulk /ω(ω + iγ). For graphene, we use the local-RPA conductivity [36,107], which we correct in the following expression to simultaneously account for inelastic attenuation and finite temperature T in both intraband and interband transitions [45]:…”

Section: Appendix D: Drude Parameters For Noble Metals and Graphenementioning

confidence: 99%

Plasmonics in atomically thin materials

Abajo

Manjavacas

2015

Faraday Discuss.

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The observation and electrical manipulation of infrared surface plasmons in graphene have triggered a search for similar photonic capabilities in other atomically thin materials that enable electrical modulation of light at visible and near-infrared frequencies, as well as strong interaction with optical quantum emitters. Here, we present a simple analytical description of the optical response of such kinds of structures, which we exploit to investigate their application to light modulation and quantum optics. Specifically, we show that plasmons in one-atom-thick noble-metal layers can be used both to produce complete tunable optical absorption and to reach the strong-coupling regime in the interaction with neighboring quantum emitters. Our methods are applicable to any plasmon-supporting thin materials, and in particular, we provide parameters that allow us to readily calculate the response of silver, gold, and graphene islands. Besides their interest for nanoscale electro-optics, the present study emphasizes the great potential of these structures for the design of quantum nanophotonics devices.

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Space-time dispersion of graphene conductivity

Cited by 746 publications

References 25 publications

Signature of Schwinger's pair creation rate via radiation generated in graphene by strong electric current

Signature of Schwinger's pair creation rate via radiation generated in graphene by strong electric current

Hybrid Surface-Phonon-Plasmon Polariton Modes in Graphene/Monolayer h-BN Heterostructures

Plasmonics in atomically thin materials

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