Automated tuning of a ring-assisted MZI-based interleaver for Kerr frequency combs.

We demonstrate a compact ring-assisted Mach-Zehnder interferometer (RAMZI)-based silicon photonic interleaver with a 400 GHz free spectral range (FSR), featuring flat passbands exceeding a spectral range of 50 nm. Additionally, we introduce a novel, to the best of our knowledge, add-on structure and tuning method enabling automated compensation for fabrication imperfections, precise shaping of the RAMZI flat-top passbands, and alignment with Kerr comb lines. Experimental results have shown successful interleaving of eight channels of distributed-feedback (DFB) lasers as well as a 200 GHz Kerr comb, both achieving an extinction ratio of approximately 20 dB.

Clearing a path for light through non-Hermitian media.

The performance of all active photonic devices today is greatly limited by loss. Here, we show that one can engineer a low loss path in a metal-clad lossy multi-mode waveguide while simultaneously achieving high-performance active photonic devices. We leverage non-Hermitian systems operating beyond the exceptional point to enable the redistribution of losses in a multi-mode photonic waveguide.

The History and Impact of Prescribing Orthokeratology for Slowing Myopia Progression.

This paper discusses the history and impact of orthokeratology on slowing the progression of myopia. It discusses the origins and evolution of orthokeratology from polymethymethaccrylate lenses worn during the day to its current prescribing of highly permeable, innovative reverse-geometry designs worn only while sleeping. Technological advances in corneal topography, lens design, lens materials, and manufacturing have facilitated growth of orthokeratology to a precise and predictable procedure.