Deng, Q., El-Saeed, A. H., Elshazly, A., Lepage, G., Marchese, C., Neutens, P., ... & Van Campenhout, J. (2024). Low-Loss and Low-Power Silicon Ring Based WDM 32×100 GHz Filter Enabled by a Novel Bend Design. arXiv preprint arXiv:2411.15025.
This research paper aims to address the limitations of conventional silicon ring resonators, particularly in achieving low loss, low power consumption, and large free spectral range (FSR) simultaneously, which are crucial for high-performance wavelength division multiplexing (WDM) applications.
The authors propose a novel bend design called TOPIC (Third Order Polynomial Interconnected Circular) based on rigorous mathematical derivations for waveguide loss optimization. They fabricate and characterize silicon ring resonators with varying radii incorporating the TOPIC bends. The performance of these resonators is evaluated in terms of FSR, roundtrip loss, thermal tuning power, and their application in a 32×100 GHz WDM filter.
The TOPIC bend design offers a superior alternative to conventional bends in silicon photonics, enabling the realization of ultra-compact, low-loss, and energy-efficient ring resonators. This breakthrough facilitates high-performance WDM systems with increased channel capacity and reduced power consumption.
This research significantly advances the field of silicon photonics by introducing a novel bend design that overcomes critical limitations of existing ring resonators. The demonstrated performance improvements in WDM applications hold significant potential for high-speed data communication and optical interconnects.
While the TOPIC bend demonstrates remarkable performance, further optimization of the design parameters considering fabrication variations and sidewall roughness could lead to even lower losses. Exploring the application of TOPIC bends in other photonic devices beyond ring resonators could unlock further possibilities for miniaturization and performance enhancement.
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