Achieving Equally-Spaced Brillouin frequency combs based on optoelectronic oscillator

IF 3.1 3区物理与天体物理 Q2 INSTRUMENTS & INSTRUMENTATION

Infrared Physics & Technology Pub Date : 2025-02-25 DOI:10.1016/j.infrared.2025.105800

Yang Li, Enming Xu, Zuxing Zhang

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引用次数: 0

Abstract

An innovative approach has been proposed to achieve a precisely equidistant Brillouin Frequency Comb (BFC). Experimental validation was performed through the integration of a Brillouin fiber laser with an Optoelectronic Oscillator (OEO). By leveraging Brillouin gain, the transition from phase modulation to intensity modulation was successfully achieved, resulting in the generation of an equidistant Optical Frequency Comb (OFC) with intervals that strictly match the Brillouin frequency shift. Specifically exciting only the first-order Stokes light within the optical fiber notably enhanced the side-mode suppression ratio of microwave signals. In our experiments, the following achievements were realized: a 7-line Optical Frequency Comb (OFC) with a frequency spacing of 10.398 GHz and a flatness of 2.48 dB. At an offset frequency of 10 kHz, the corresponding phase noise of the microwave signal was measured at −101.534 dBc/Hz. Furthermore, by manipulating the optical and electrical gains of the OEO, the capability to realize OFCs with varying frequency spacings was demonstrated. The proposed OEO addresses the issue of BFCs, where the comb spacing is not strictly uniform, leading to their slow development in the fields of optical communications, precise measurements, and more.

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基于光电振荡器的等间隔布里渊频率梳的实现

提出了一种实现精确等距布里渊频率梳（BFC）的创新方法。通过将布里渊光纤激光器与光电振荡器（OEO）集成进行实验验证。通过利用布里渊增益，成功地实现了从相位调制到强度调制的过渡，从而产生了间隔与布里渊频移严格匹配的等距光频梳（OFC）。在光纤中只激发一阶Stokes光，显著提高了微波信号的侧模抑制比。在我们的实验中，实现了以下成果：频率间隔为10.398 GHz，平坦度为2.48 dB的7线光频梳（OFC）。在偏移频率为10 kHz时，测量到微波信号对应的相位噪声为- 101.534 dBc/Hz。此外，通过操纵OEO的光学和电气增益，证明了实现不同频率间隔OFCs的能力。提出的OEO解决了bfc的问题，其中梳间距不是严格均匀的，导致其在光通信，精确测量等领域发展缓慢。

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来源期刊

Infrared Physics & Technology 物理-光学

CiteScore

5.70

自引率

12.10%

发文量

400

审稿时长

67 days

期刊介绍： The Journal covers the entire field of infrared physics and technology: theory, experiment, application, devices and instrumentation. Infrared'' is defined as covering the near, mid and far infrared (terahertz) regions from 0.75um (750nm) to 1mm (300GHz.) Submissions in the 300GHz to 100GHz region may be accepted at the editors discretion if their content is relevant to shorter wavelengths. Submissions must be primarily concerned with and directly relevant to this spectral region. Its core topics can be summarized as the generation, propagation and detection, of infrared radiation; the associated optics, materials and devices; and its use in all fields of science, industry, engineering and medicine. Infrared techniques occur in many different fields, notably spectroscopy and interferometry; material characterization and processing; atmospheric physics, astronomy and space research. Scientific aspects include lasers, quantum optics, quantum electronics, image processing and semiconductor physics. Some important applications are medical diagnostics and treatment, industrial inspection and environmental monitoring.