a, Thin-film lithium niobate microresonator Raman lasing suppression methods, including free spectral range (FSR) engineering and dissipation spectrum engineering (top and bottom panels, respectively). In the former, the microresonator FSR is ideally larger than the Raman gain bandwidth, and the Raman gain peak placed in between Raman modes, such that the effective Raman gain coefficient is reduced for Raman modes. In the latter, the microresonator is lossy at Raman mode frequencies, due to excess coupling between the microresonator and bus waveguide. Both methods maintain a critically coupled pump mode and increase the Raman lasing threshold, such that the Kerr parametric oscillation threshold may be lower. b, Entirely connected, octave-spanning dissipative Kerr soliton (DKS) frequency comb spectra from dispersion-engineered microresonators, utilizing the FSR engineering method (blue) and the dissipation engineering method (green).
Newswise — The invention of optical frequency combs revolutionized frequency metrology and time-keeping. Miniaturization of such combs onto photonic chips, primarily leveraging the microresonator Kerr soliton frequency comb, expands on these functionalities by providing portable solutions to ultrafast spectroscopy, laser frequency synchronization, as well as stable optical, millimeter wave, and microwave frequency generation. For many such applications, low-noise soliton frequency combs are required, yet stabilization of the soliton repetition rate and carrier-envelope offset typically requires complicated off-chip machinery such as frequency doubling and electro-optic division. The ultralow-loss thin-film lithium niobate photonic platform, with its strong electro-optic effect and efficient second-harmonic generation, holds promise in hosting integrated frequency combs fully-stabilized by on-chip components. However, octave-spanning solitons with entirely connected spectrum, suitable for stabilization by integrated electro-optic modulators and periodically-poled waveguides, have not been demonstrated. This is in part due to lithium niobate microresonators exhibiting low-threshold Raman lasing, a nonlinear process in competition with the Kerr effect that initiates parametric oscillation and mode-locks soliton states. Therefore, precise guidelines are needed to suppress Raman lasing in lithium niobate microresonators, which would not only enable octave-spanning soliton sources, but also facilitate their chip-scale stabilization and reliable integration into large-scale photonic systems.
“Thin-film lithium niobate has proven to be a very powerful material for photonics” said Yunxiang Song, a PhD student in Quantum Science and Engineering at Harvard University. “So, our goal was to develop a comprehensive understanding for soliton microcomb generation on this platform, so they could be used in conjunction with its well-established active modulation and frequency conversion capabilities, ultimately for building better integrated comb sources”.
In a new paper (doi: https://doi.org/10.1038/s41377-024-01546-7) published in Light: Science & Applications, a team of scientists, led by Professors Marko LonĨar and Kiyoul Yang from the John A. Paulson School of Engineering and Applied Sciences at Harvard University, have made progress towards this goal. They demonstrated octave-spanning Kerr soliton frequency combs on the thin-film lithium niobate photonic platform. They also established design rules, based on engineering the microresonator mode spacing and dissipation profile, that consistently suppresses Raman lasing in favor of soliton frequency comb generation. Specifically, when the microresonator mode spacing is made larger than the Raman gain bandwidth, they showed an octave-spanning soliton spanning 131 to 263 THz. Even better, when dissipation near Raman lasing modes was increased using a pulley-type coupling, they achieved over 88% success rate in fabricating soliton-supporting microresonators across different designs, including various dispersions and resonator sizes, and also showed an octave-spanning soliton spanning 126 to 252 THz with no spectral gaps.
The reported Raman suppression method may accelerate future development of soliton frequency combs on thin-film lithium niobate, as well as enable straightforward nonlinear frequency comb generation in other emerging electro-optic, crystalline materials such as thin-film lithium tantalate, where interfering Raman lasing is expected to play a role. Additionally, the entirely connected, octave-spanning soliton states may unlock system-level demonstrations, such as optical frequency synthesis and comb-referenced laser spectroscopy.
The team believes that “although still in its early stages, the reliable fabrication of octave-spanning soliton frequency combs shows potential for developing monolithic and compact comb-driven photonic systems based on thin-film lithium niobate”.
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References
DOI
Original Source URL
https://doi.org/10.1038/s41377-024-01546-7
Funding information
This work is supported by the Defense Advanced Research Projects Agency (HR001120C0137, D23AP00251-00), Office of Naval Research (N00014-22-C-1041), National Science Foundation (OMA-2137723, OMA2138068), U.S. Navy (N68335-22-C-0413), and National Research Foundation of Korea.
About Light: Science & Applications
The Light: Science & Applications will primarily publish new research results in cutting-edge and emerging topics in optics and photonics, as well as covering traditional topics in optical engineering. The journal will publish original articles and reviews that are of high quality, high interest and far-reaching consequence.
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