Periodic Reporting for period 4 - DarkComb (Dark-Soliton Engineering in Microresonator Frequency Combs)
Período documentado: 2022-11-01 hasta 2023-10-31
However, one practical concern when dealing with a single-laser source for wavelength division multiplexing is the amount of power that can be obtained per channel. A key outstanding issue with microresonator frequency combs is that they display relatively low power conversion efficiency, meaning that only a fraction of the input power of the laser is successfully transferred to the new frequency components. The overall objective of DarkComb is to investigate a novel microresonator comb source called “dark soliton”, which displays unusually high-power conversion efficiency, but has been very little investigated by the research community. This aim requires: (1) to understand the fundamental complex nonlinear interactions of dark solitons in optical microresonators, (2) to develop a suitable arrangement of ultra-low-loss microresonators for generating dark solitons with a performance compatible with fiber communication systems and (3) to realize system-level experiments demonstrating unprecedented communication speeds. If successful, the DarkComb project will mark the start of a new, practical, high-performance and compact technology platform that will enable the next generation of optical communication systems.
With our microcombs, and in collaboration with the Technical University of Denmark, we have demonstrated that microcombs offer the performance required to power the next-generation transmission systems. To be more concrete, we have demonstrated that a single microcomb has the performance to transmit data beyond one petabit per second (results under peer review). This results from the unique combination of microcomb technology with multi-core optical fiber.
During the final stage of the project we have focused on unraveling the phase noise dynamics of this dual-comb cavity arrangement and establishing pioneering demonstrations for dual-comb interferometry and spectroscopy. We have also contributed to the development of a new class of photonic molecule microcomb based on anomalous dispersion coupled cavities with >10x higher optical conversion efficiency than state of the art.
Based on this platform we have demonstrated, numerically and experimentally, an arrangement of linearly coupled cavities that results in microcombs with record-high conversion efficiency and reproducibility.
We have demonstrated a novel system-level architecture that dramatically simplifies the receiver scheme in fiber-optic communications, that utilizes an inherent physical property of frequency combs.
Finally, we have for the first time, demonstrated a fiber-optic communication system in the petabit per second regime using a single microcomb, unravelled the phase noise dynamics and realized dual-comb interferometry.
These results have significantly advanced the knowledge of microresonator frequency combs, demonstrated their unique performance in a number of applications (from optical communications to spectroscopy) and paved the way for their practical deployment in demanding applications.