Nature Communications (Mar 2024)

Near-field detection of gate-tunable anisotropic plasmon polaritons in black phosphorus at terahertz frequencies

  • Eva A. A. Pogna,
  • Valentino Pistore,
  • Leonardo Viti,
  • Lianhe Li,
  • A. Giles Davies,
  • Edmund H. Linfield,
  • Miriam S. Vitiello

DOI
https://doi.org/10.1038/s41467-024-45264-5
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Polaritons in two-dimensional layered crystals offer an effective solution to confine, enhance and manipulate terahertz (THz) frequency electromagnetic waves at the nanoscale. Recently, strong THz field confinement has been achieved in a graphene-insulator-metal structure, exploiting THz plasmon polaritons (PPs) with strongly reduced wavelength (λ p ≈ λ 0/66) compared to the photon wavelength λ 0. However, graphene PPs propagate isotropically, complicating the directional control of the THz field, which, on the contrary, can be achieved exploiting anisotropic layered crystals, such as orthorhombic black-phosphorus. Here, we detect PPs, at THz frequencies, in hBN-encapsulated black phosphorus field effect transistors through THz near-field photocurrent nanoscopy. The real-space mapping of the thermoelectrical near-field photocurrents reveals deeply sub-wavelength THz PPs (λ p ≈ λ 0/76), with dispersion tunable by electrostatic control of the carrier density. The in-plane anisotropy of the dielectric response results into anisotropic polariton propagation along the armchair and zigzag crystallographic axes of black-phosphorus. The achieved directional subwavelength light confinement makes this material system a versatile platform for sensing and quantum technology based on nonlinear optics.