Graphene plasmonics

Graphene is a 2D nanosheet with atomic thin thickness in terms of 0.34 nm. Due to the ultrathin thickness, graphene showed many properties that are quite different from their bulk graphite counterparts. The most prominent advantages are known to be their high electron mobility and high mechanical strengths.[1][2] Thus, it exhibits potential for applications in optics and electronics especially for the development of wearable devices as flexible substrates. More importantly, the optical absorption rate of graphene is 2.3% in the visible and near-infrared region. This broadband absorption characteristic also attracted great attention of the research community to exploit the graphene-based photodetectors/modulators.[3][4]

Plasmons are collective electron oscillations usually excited at metal surfaces by a light source. Doped graphene layers have also shown the similar surface plasmon effects to that of metallic thin films.[5][6] Through the engineering of metallic substrates or nanoparticles (e.g., gold, silver and copper) with graphene, the plasmonic properties of the hybrid structures could be tuned for improving the optoelectronic device performances.[7][8] It is worth noting that the electrons at the metallic structure could transfer to the graphene conduction band. This is attributed to the zero bandgap property of graphene nanosheet.

Application

When the plasmons were resonant at the graphene/metal surface, a strong electric field would be induced which could enhance the generation of electron-hole pairs in the graphene layer.[9][10] The excited electron carrier numbers linearly increased with the field intensity based on the Fermi’s rule. The induced charge carriers of metal/graphene hybrid nanostructure could be up to 7 times higher than that of pristine graphene ones due to the plasmonic enhancement.

So far, the graphene plasmonic effects have been demonstrated for different applications ranging from light modulation to biological/chemical sensing.[11][12][13] High-speed photodetection at 10 Gbit/s based on graphene and 20-fold improvement on the detection efficiency through graphene/gold nanostructure were also reported.[14] Graphene plasmonics are considered as good alternatives to the noble metal plasmons not only due to their cost-effectiveness for large-scale production but also by the higher confinement of the plasmonics at the graphene surface.[15][16] The enhanced light-matter interactions could further be optimized and tuned through electrostatic gating. These advantages of graphene plasmonics paved a way to achieve single-molecule detection and single-plasmon excitation.

See also

References

  1. Grigorenko, A. N.; Polini, M.; Novoselov, K. S. (2012). "Graphene plasmonics". Nature Photonics. 6: 749–758. doi:10.1038/nphoton.2012.262.
  2. Ju, L.; et al. (2011). "Graphene plasmonics for tunable terahertz metamaterials". Nature Nanotechnology. 6: 630–634. doi:10.1038/nnano.2011.146.
  3. Constant, T. J.; Hornett, S. M.; Chang, D. E.; Hendry, E. (2016). "All-optical generation of surface plasmons in graphene". Nature Physics. 12: 124–127. doi:10.1038/nphys3545.
  4. Wong, L. J.; Kaminer, I.; Ilic, O.; Joannopoulos, J.D.; Soljačić, M. (2016). "Towards graphene plasmon-based free-electron infrared to X-ray sources". Nature Photonics. 10: 46–52. doi:10.1038/nphoton.2015.223.
  5. Koppens, F.H.L.; Chang, D.E.; García de Abajo, F.J. (2011). "Graphene plasmonics: A platform for strong light–matter interactions". Nano Letters. 11: 3370–3377. doi:10.1021/nl201771h.
  6. Yan, H.; Low, T.; Zhu, W.; Wu, Y.; Freitag, M.; Li, X.; Guinea, F.; Avouris, P.; Xia, F. (2013). "Damping pathways of mid-infrared plasmons in graphene nanostructures". Nano Letters. 7: 394–399. doi:10.1038/nphoton.2013.57.
  7. Fang, Z.; Liu, Z.; Wang, Y.; Ajayan, P. M.; Nordlander, P.; Halas, N.J. (2012). "Graphene-antenna sandwich photodetector". Nano Letters. 12: 3808–3813. doi:10.1021/nl301774e.
  8. Huidobro, P. A.; Kraft, M.; Maier, S. A.; Pendry, J. B. (2016). "Graphene as a tunable anisotropic or isotropic plasmonic metasurface". Acs Nano. 10: 5499–5506. doi:10.1021/acsnano.6b01944.
  9. Jadidi, M. M.; et al. (2015). "Tunable Terahertz hybrid metal−graphene plasmons". Nano Letters. 15: 7099−7104. doi:10.1021/acs.nanolett.5b03191.
  10. Fernandez-Dominguez, A.I.; Garcia-Vidal, F. J.; Martin-Moreno, L. (2017). "Unrelenting plasmons". Nature Photonics. 11: 8–10. doi:10.1038/nphoton.2016.258.
  11. Chen, J.; Badioli, M.; Alonso-Gonzalez, P.; Thongrattanasiri, S.; Huth, F.; Osmond, J.; Spasenovic, M.; Centeno, A.; Pesquera, A.; Godignon, P.; Zurutuza Elorza, A.; Camara, N.; García de Abajo, F.J.; Hillenbrand, R.; Koppens, F.H.L. (2012). "Optical nano-imaging of gate-tunable graphene plasmons". Nature. 487: 77–81. doi:10.1038/nature11254.
  12. Zeng, S.; et al. (2015). "Graphene-gold metasurface architectures for ultrasensitive plasmonic biosensing" (PDF). Advanced Materials. 27: 1–7. doi:10.1002/adma.201501754.
  13. Rodrigo, D.; Limaj, O.; Janner, D.; Etezadi, D.; García-de-Abajo, F.J.; Pruneri, V.; Altug, H. (2015). "Mid-infrared plasmonic biosensing with graphene". Science. 349 (6244): 165–168. doi:10.1126/science.aab2051.
  14. Echtermeyer, T. J.; Britnell, L.; Jasnos, P. K.; Lombardo, A.; Gorbachev, R. V.; Grigorenko, A. N.; Geim, A. K.; Ferrari, A. C.; Novoselov, K. S. (2011). "Strong plasmonic enhancement of photovoltage in graphene". Nature Communications. 2: 458. doi:10.1038/ncomms1464.
  15. García de Abajo, F.J. (2014). "Graphene plasmonics: Challenges and opportunities". ACS Photonics. 1: 135−152. doi:10.1021/ph400147y.
  16. Fei, Z.; Rodin, A. S.; Gannett, W.; Dai, S.; Regan, W.; Wagner, M.; Liu, M. K.; McLeod, A. S.; Dominguez, G.; Thiemens, M.; Castro Neto, Antonio H.; Keilmann, F.; Zettl, A.; Hillenbrand, R.; Fogler, M. M.; Basov, D.N. (2013). "Electronic and plasmonic phenomena at graphene grain boundaries". Nature Nanotechnology. 8: 821–825. doi:10.1038/nnano.2013.197.
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