On-chip Photonics
Extreme Skin-depth Waveguides
Ultra-compact, densely integrated optical components manufactured on a CMOS-foundry platform are highly desirable for optical information processing and electronic-photonic co-integration. However, the large spatial extent of evanescent waves arising from nanoscale confinement, ubiquitous in silicon photonic devices, causes significant cross-talk and scattering loss. Here, we demonstrate that anisotropic all-dielectric metamaterials open a new degree of freedom in total internal reflection to shorten the decay length of evanescent waves. We experimentally show the reduction of cross-talk by greater than 30 times and the bending loss by greater than 3 times in densely integrated, ultra-compact photonic circuit blocks. Our prototype all-dielectric metamaterial-waveguide achieves a low propagation loss of approximately 3.7±1.0 dB/cm, comparable to those of silicon strip waveguides. Our approach marks a departure from interference-based confinement as in photonic crystals or slot waveguides, which utilize nanoscale field enhancement. Its ability to suppress evanescent waves without substantially increasing the propagation loss shall pave the way for all-dielectric metamaterial-based dense integration.
Selected papers on extreme skin-depth waveguides:
Transparent subdiffraction optics: nanoscale light confinement without metal S Jahani, Z Jacob Optica 1 (2), 96-100
Controlling evanescent waves using silicon photonic all-dielectric metamaterials for dense integration S Jahani, S Kim, J Atkinson, JC Wirth, F Kalhor, AA Noman, WD Newman, Nature communications 9 (1), 1893 (2018)
TRAPPING LIGHT THAT DOESN'T BOUNCE OFF TRACK FOR FASTER ELECTRONICS
WEST LAFAYETTE, Ind. — Replacing traditional computer chip components with light-based counterparts will eventually make electronic devices faster due to the wide bandwidth of light.
An anisotropic metamaterial waveguide cladding keeps light travel on track throughout a computer chip, preventing leaked and jumbled bits of information.
Jahani, Saman, et al. "Controlling evanescent waves using silicon photonic all-dielectric metamaterials for dense integration." Nature communications 9.1 (2018): 1893. |