Remote Residual Instability Evaluation of Comb-Based Precise Frequency Transmission for Optical Clock

Li, Zhaolong; Gui, Sibo; Wu, Haitao; Guo, Ziyu; Zhao, Jianye

doi:10.3390/photonics10111188

Photonics

2023

DOI: 10.3390/photonics10111188

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Remote Residual Instability Evaluation of Comb-Based Precise Frequency Transmission for Optical Clock

Zhaolong Li,

Sibo Gui,

Haitao Wu

et al.

Abstract: Optical clocks can be used as the absolute frequency reference due to their high accuracy and stability. In a precise optical clock transmission system, the instability loss of the link is usually evaluated by beating the remote optical signal with the reference clock, which is not suitable for real frequency distribution applications. Therefore, it is necessary to assess the performance directly at the remote site for the optical frequency transfer, because the two sites of the link are usually not co-located… Show more

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Effects of dissipation rates on dispersive waves and mode families in microresonators with avoided mode-crossing

Jiao,

Xu,

Liu

et al. 2024

Opt. Express

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In microresonators with avoided mode-crossing, the dispersive waves and mode families can be affected by dissipation rates, which also cause different hysteresis of the dispersive waves. Based on the Lugiato-Lefever equations and the single-mode dispersive wave model, the effects of dissipation rates on dispersive waves and mode families in microresonators are investigated. Results showed that the dispersive wave power curve exhibits hysteresis because of the avoided mode-crossing and the frequency shift curves can be convex, contrary to the absence of hysteresis. Moreover, the distribution of the two mode families in the microresonator is different at various detuning frequencies due to the dispersive wave, and it is relatively flat in the hysteresis state. The dispersive wave power and frequency shift are varied due to the different dissipation rates. The power of the two mode families decreases with the increase in mode dissipations. The results are significant for investigating dissipative Kerr solitons associated with dispersive waves in microresonators with avoided mode-crossing in practice.

show abstract

Effects of dissipation rates on dispersive waves and mode families in microresonators with avoided mode-crossing

Jiao,

Xu,

Liu

et al. 2024

Opt. Express

View full text Add to dashboard Cite

show abstract

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Remote Residual Instability Evaluation of Comb-Based Precise Frequency Transmission for Optical Clock

Cited by 1 publication

References 25 publications

Effects of dissipation rates on dispersive waves and mode families in microresonators with avoided mode-crossing

Effects of dissipation rates on dispersive waves and mode families in microresonators with avoided mode-crossing

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