Tailoring the pulse train of an optical frequency comb with a magnetized atomic medium

Yan, Yang; Yuan, Jinpeng; Wang, Lirong; Liu, Xiao; Jia, Suotang

doi:10.1088/1612-202x/ac9062

Cited by 2 publications

(2 citation statements)

References 31 publications

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“…However, in some applications where frequency standards with high power and high signal-to-noise ratio (SNR) are required, the lines in OFCs are difficult to be employed directly. The extraction and manipulation of DOI: 10.1002/lpor.202300769 one or several comb lines can greatly enrich the applications of OFCs, for instance, atoms cooling, [5] spectroscopy, [6,7] microwave photonics, [8][9][10] and arbitrary optical waveform generation. [11,12] Furthermore, any arbitrary line extracted from the wide spectrum of an OFC can serve as an outstanding singlelongitudinal-mode continuous-wave (CW) laser, namely a high-precision optical synthesizer.…”

Section: Introductionmentioning

confidence: 99%

Highly Discriminative Amplification of a Single Frequency Comb Line

Xiong,

Zhou,

Cao

et al. 2023

Laser & Photonics Reviews

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The optical power of a single line in optical frequency combs (OFCs) is inherently weak, so the extraction and amplification of a single OFC line is required for many high‐precision applications. In this work, a high gain, narrowband, and all‐polarization‐maintaining (PM) fiber Brillouin amplifier is introduced to address this issue. The use of PM fiber as the gain medium provides higher Brillouin gain and avoids polarization sensitivity to thermal and acoustic disturbance. The gain fiber is reduced to tens of meters with higher pump power, which is beneficial for the phase quality of the amplified comb line. Numerical simulations and experiments are performed to investigate the features of the Brillouin amplification process for an individual OFC line. Notably, direct generation of a Watt‐level single‐mode laser from an OFC is demonstrated, with a signal‐to‐noise‐ratio (SNR) of 47 dB and a side‐mode‐suppression‐ratio (SMSR) exceeding 60 dB, which represents the highest power, and best SNR and SMSR performance ever reported, to the best of the knowledge.

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Section: Introductionmentioning

confidence: 99%

Highly Discriminative Amplification of a Single Frequency Comb Line

Xiong,

Zhou,

Cao

et al. 2023

Laser & Photonics Reviews

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“…On the other hand, several GHz equiva-lent noise bandwidth has been realized at > 80% transmission in passive designs [45,46]. A fundamental limit on linewidths has not yet been found and could have future implications for metrology [47][48][49].…”

Section: Introductionmentioning

confidence: 99%

Exploiting non-orthogonal eigenmodes in a non-Hermitian optical system to realize sub-100 MHz magneto-optical filters.

Logue¹,

Briscoe²,

Pizzey³

et al. 2023

Preprint

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Non-Hermitian physics is responsible for many of the counter-intuitive effects observed in optics research opening up new possibilities in sensing, polarization control and measurement. A hallmark of non-Hermitian matrices is the possibility of non-orthogonal eigenvectors resulting in coupling between modes. The advantages of propagation mode coupling have been little explored in magneto-optical filters and other devices based on birefringence. Magneto-optical filters select for ultra-narrow transmission regions by passing light through an atomic medium in the presence of a magnetic field. Passive filter designs have traditionally been limited by Doppler broadening of thermal vapors. Even for filter designs incorporating a pump laser, transmissions are typically less than 15% for sub-Doppler features. Here we exploit our understanding of non-Hermitian physics to induce non-orthogonal propagation modes in a vapor and realize better magneto-optical filters. We construct two new filter designs with ENBWs and maximum transmissions of 181 MHz, 42 % and 140 MHz, 17% which are the highest figure of merit and first sub-100 MHz FWHM passive filters recorded respectively. This work opens up a range of new filter applications including metrological devices for use outside a lab setting and commends filtering as a new candidate for deeper exploration of non-Hermitian physics such as exceptional points of degeneracy.

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Tailoring the pulse train of an optical frequency comb with a magnetized atomic medium

Cited by 2 publications

References 31 publications

Highly Discriminative Amplification of a Single Frequency Comb Line

Highly Discriminative Amplification of a Single Frequency Comb Line

Exploiting non-orthogonal eigenmodes in a non-Hermitian optical system to realize sub-100 MHz magneto-optical filters.

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