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Nanometer-scale photon confinement in topology-optimized dielectric cavities

Author

Listed:
  • Marcus Albrechtsen

    (Technical University of Denmark)

  • Babak Vosoughi Lahijani

    (Technical University of Denmark
    Technical University of Denmark)

  • Rasmus Ellebæk Christiansen

    (Technical University of Denmark
    Technical University of Denmark)

  • Vy Thi Hoang Nguyen

    (Technical University of Denmark)

  • Laura Nevenka Casses

    (Technical University of Denmark
    Technical University of Denmark
    Technical University of Denmark)

  • Søren Engelberth Hansen

    (Technical University of Denmark
    Technical University of Denmark)

  • Nicolas Stenger

    (Technical University of Denmark
    Technical University of Denmark
    Technical University of Denmark)

  • Ole Sigmund

    (Technical University of Denmark
    Technical University of Denmark)

  • Henri Jansen

    (Technical University of Denmark)

  • Jesper Mørk

    (Technical University of Denmark
    Technical University of Denmark)

  • Søren Stobbe

    (Technical University of Denmark
    Technical University of Denmark)

Abstract

Nanotechnology enables in principle a precise mapping from design to device but relied so far on human intuition and simple optimizations. In nanophotonics, a central question is how to make devices in which the light-matter interaction strength is limited only by materials and nanofabrication. Here, we integrate measured fabrication constraints into topology optimization, aiming for the strongest possible light-matter interaction in a compact silicon membrane, demonstrating an unprecedented photonic nanocavity with a mode volume of V ~ 3 × 10−4 λ3, quality factor Q ~ 1100, and footprint 4 λ2 for telecom photons with a λ ~ 1550 nm wavelength. We fabricate the cavity, which confines photons inside 8 nm silicon bridges with ultra-high aspect ratios of 30 and use near-field optical measurements to perform the first experimental demonstration of photon confinement to a single hotspot well below the diffraction limit in dielectrics. Our framework intertwines topology optimization with fabrication and thereby initiates a new paradigm of high-performance additive and subtractive manufacturing.

Suggested Citation

  • Marcus Albrechtsen & Babak Vosoughi Lahijani & Rasmus Ellebæk Christiansen & Vy Thi Hoang Nguyen & Laura Nevenka Casses & Søren Engelberth Hansen & Nicolas Stenger & Ole Sigmund & Henri Jansen & Jespe, 2022. "Nanometer-scale photon confinement in topology-optimized dielectric cavities," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
  • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-33874-w
    DOI: 10.1038/s41467-022-33874-w
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    References listed on IDEAS

    as
    1. Niels Aage & Erik Andreassen & Boyan S. Lazarov & Ole Sigmund, 2017. "Giga-voxel computational morphogenesis for structural design," Nature, Nature, vol. 550(7674), pages 84-86, October.
    2. N. A. Mortensen & S. Raza & M. Wubs & T. Søndergaard & S. I. Bozhevolnyi, 2014. "A generalized non-local optical response theory for plasmonic nanostructures," Nature Communications, Nature, vol. 5(1), pages 1-7, September.
    3. J. A. Rogers & M. G. Lagally & R. G. Nuzzo, 2011. "Synthesis, assembly and applications of semiconductor nanomembranes," Nature, Nature, vol. 477(7362), pages 45-53, September.
    4. Yoshihiro Akahane & Takashi Asano & Bong-Shik Song & Susumu Noda, 2003. "High-Q photonic nanocavity in a two-dimensional photonic crystal," Nature, Nature, vol. 425(6961), pages 944-947, October.
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