Physics

Near-Zero-Dispersion Broadband Modulational Instability and the Soliton Kerr Microcombs are Dispersed Anomalously

Near-Zero-Dispersion Broadband Modulational Instability and the Soliton Kerr Microcombs are Dispersed Anomalously

Microcombs, which are frequency combs based on microresonators, have generated a great deal of interest in recent years due to their ground-breaking capabilities of small size, adjustable comb spacing, and wide bandwidth. Numerous uses for microcombs have been reported, including optical frequency synthesizer, atomic clock, lidar, spectroscopy, and optical communications.

For these applications, it is essential that the microcombs simultaneously maintain a narrow mode spacing (typically < 50 GHz) and a wide spectrum coverage. However, it is still very difficult for microcomb generating techniques because of waveguide loss or dispersion control limitations.

In a new paper published in Light: Science & Applications, a team of scientists, led by Professor Kan Wu from Shanghai Jiao Tong University, and Professor Baicheng Yao from University of Electronic Science and Technology of China, explores the dynamics of Kerr comb generation in the near-zero anomalous-dispersion regime.

Thanks to the ultra-small anomalous group-velocity dispersion, they have experimentally obtained a 2/3-octave-spaning microcomb in the broadband modulational instability (MI) state with a spectrum from 1240 nm to 1950 nm and a mode spacing of 10 GHz. The corresponding number of comb lines is more than 8400.

The microcombs in broadband MI state and near-zero-dispersion soliton state possess their own potential application scenarios. The MI microcomb state has advantages of high conversion efficiency and widely accessible range, which is suitable for the high power microcomb application. In contrast, near-zero-dispersion soliton state has relatively low phase-noise feature and self-organized structures, which provides unique capabilities in the applications of optical computing, light sensing, communication and spectroscopy, etc. This work presents a flexible strategy to choose the operating state of the microcombs depending on the requirement of the application.

The scientists

Moreover, they have observed a novel soliton structure in near-zero anomalous-dispersion regime, and term these solitons as “anomalous-dispersion based near-zero-dispersion soliton.”

This near-zero-dispersion soliton (NZDS) has tightly packed multi-soliton structures with local repetition frequency up to 8.6 THz and individual pulse width less than 100 fs. The corresponding spectral span is >32 THz and the comb line number is >3200.

The described method offers fresh insight into the Kerr microcombs’ nonlinear dynamics in the vicinity of the zero-dispersion domain and offers a workable method for creating a broad microcomb with numerous comb lines.

This work is performed in a high-Q Fabry-Perot microresonator based on highly nonlinear fiber. The fiber F-P microresonator is a flexible platform to study the Kerr soliton dynamics near zero-dispersion region.

Since mode-crossing effects in integrated multimode microresonators and periodic disturbances brought on by dispersive waves in a long fiber cavity are eliminated, this platform ensures that the observed phenomena are true to pure χ(3) nonlinearity and high-order dispersion. These scientists summarize the technical characteristics of their work.

“We adopt a pulsed pumping scheme to drive this near-zero dispersion F-P microresonator. Pulsed pumping scheme can effectively reduce the demand for average pumping power and alleviate the intracavity thermal effect.”

“The microcombs in broadband MI state and near-zero-dispersion soliton state possess their own potential application scenarios. The MI microcomb state has advantages of high conversion efficiency and widely accessible range, which is suitable for the high power microcomb application. In contrast, near-zero-dispersion soliton state has relatively low phase-noise feature and self-organized structures, which provides unique capabilities in the applications of optical computing, light sensing, communication and spectroscopy, etc. This work presents a flexible strategy to choose the operating state of the microcombs depending on the requirement of the application,” the scientists say.