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Surface plasmon polariton graphene photodetectors

The combination of plasmonic nanoparticles and graphene enhances the responsivity and spectral selectivity of graphene-based photodetectors. However, the small area of the metal-graphene junction, where the induced electron-hole pairs separate, limits the photoactive region to sub-micron length scales. Here, we couple graphene with a plasmonic grating and exploit the resulting surface plasmon polaritons to deliver the collected photons to the junction region of a metal-graphene-metal photodetector. This results into a 400% enhancement of responsivity and a 1000% increase in photoactive length, combined with tunable spectral selectivity. The interference between surface plasmon polaritons and the incident wave introduces new functionalities, such as light flux attraction or repulsion from the contact edges, enabling the tailored design of the photodetector's spectral response. This architecture can also be used for surface plasmon bio-sensing with direct-electric- readout, eliminating the need of complicated optics.

preprint2015arXivOpen access
T. J. EchtermeyerS. MilanaU. SassiA. EidenM. WuE. LidorikisA. C. Ferrari
cond-mat.mes-hallcond-mat.mtrl-sci
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Open access7 authors2 topics
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T. J. EchtermeyerS. MilanaU. SassiA. EidenM. WuE. LidorikisA. C. Ferrari

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