Nature Communications (Aug 2024)

Controlling photothermoelectric directional photocurrents in graphene with over 400 GHz bandwidth

  • Stefan M. Koepfli,
  • Michael Baumann,
  • Robin Gadola,
  • Shadi Nashashibi,
  • Yesim Koyaz,
  • Daniel Rieben,
  • Arif Can Güngör,
  • Michael Doderer,
  • Killian Keller,
  • Yuriy Fedoryshyn,
  • Juerg Leuthold

DOI
https://doi.org/10.1038/s41467-024-51599-w
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Photodetection in the near- and mid-infrared spectrum requires a suitable absorbing material able to meet the respective targets while ideally being cost-effective. Graphene, with its extraordinary optoelectronic properties, could provide a material basis simultaneously serving both regimes. The zero-band gap offers almost wavelength independent absorption which lead to photodetectors operating in the infrared spectrum. However, to keep noise low, a detection mechanism with fast and zero bias operation would be needed. Here, we show a self-powered graphene photodetector with a > 400 GHz frequency response. The device combines a metamaterial perfect absorber architecture with graphene, where asymmetric resonators induce photothermoelectric directional photocurrents within the graphene channel. A quasi-instantaneous response linked to the photothermoelectric effect is found. Typical drift/diffusion times optimization are not needed for a high-speed response. Our results demonstrate that these photothermoelectric directional photocurrents have the potential to outperform the bandwidth of many other graphene photodetectors and most conventional technologies.