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Autores principales: Xue, Shixin, Li, Mingxiao, Lopez-rios, Raymond, Ling, Jingwei, Gao, Zhengdong, Hu, Qili, Qiu, Tian, Staffa, Jeremy, Chang, Lin, Wang, Heming, Xiang, Chao, Bowers, John E., Lin, Qiang
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.07482
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author Xue, Shixin
Li, Mingxiao
Lopez-rios, Raymond
Ling, Jingwei
Gao, Zhengdong
Hu, Qili
Qiu, Tian
Staffa, Jeremy
Chang, Lin
Wang, Heming
Xiang, Chao
Bowers, John E.
Lin, Qiang
author_facet Xue, Shixin
Li, Mingxiao
Lopez-rios, Raymond
Ling, Jingwei
Gao, Zhengdong
Hu, Qili
Qiu, Tian
Staffa, Jeremy
Chang, Lin
Wang, Heming
Xiang, Chao
Bowers, John E.
Lin, Qiang
contents The invention of the laser unleashed the potential of optical metrology, leading to numerous advancements in modern science and technology. This reliance on lasers, however, also sets a bottleneck for precision optical metrology which is complicated by sophisticated photonic infrastructure required for delicate laser-wave control, leading to limited metrology performance and significant system complexity. Here we make a key step towards resolving this challenge, by demonstrating a Pockels laser with multi-functional capability that advances the optical metrology to a new level. The chip-scale laser exhibits a narrow intrinsic linewidth down to 167 Hz and a broad mode-hop-free tuning range up to 24 GHz. In particular, it offers an unprecedented frequency chirping rate up to 20 EHz/s, and an enormous modulation bandwidth >10 GHz, both orders of magnitude larger than any existing lasers. With this laser, we are able to successfully achieve velocimetry of 40 m/s at a short distance of 0.4 m, with a measurable velocity up to the first cosmic velocity at 1 m away, that is inaccessible by conventional ranging approaches, and distance metrology with a ranging resolution of <2 cm. Moreover, for the first time to the best of our knowledge, we are able to realize a dramatically simplified architecture for laser frequency stabilization, by direct locking the laser to an external reference gas cell without any extra external light control. We successfully achieve a long-term laser stability with a frequency fluctuation of only $\pm$ 6.5 MHz over 60 minutes. The demonstrated Pockels laser combines elegantly high laser coherence with ultrafast frequency reconfigurability and superior multifunctional capability that we envision to have profound impacts on many areas including communication, sensing, autonomous driving, quantum information processing, and beyond.
format Preprint
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institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pockels Laser Directly Driving Ultrafast Optical Metrology
Xue, Shixin
Li, Mingxiao
Lopez-rios, Raymond
Ling, Jingwei
Gao, Zhengdong
Hu, Qili
Qiu, Tian
Staffa, Jeremy
Chang, Lin
Wang, Heming
Xiang, Chao
Bowers, John E.
Lin, Qiang
Optics
The invention of the laser unleashed the potential of optical metrology, leading to numerous advancements in modern science and technology. This reliance on lasers, however, also sets a bottleneck for precision optical metrology which is complicated by sophisticated photonic infrastructure required for delicate laser-wave control, leading to limited metrology performance and significant system complexity. Here we make a key step towards resolving this challenge, by demonstrating a Pockels laser with multi-functional capability that advances the optical metrology to a new level. The chip-scale laser exhibits a narrow intrinsic linewidth down to 167 Hz and a broad mode-hop-free tuning range up to 24 GHz. In particular, it offers an unprecedented frequency chirping rate up to 20 EHz/s, and an enormous modulation bandwidth >10 GHz, both orders of magnitude larger than any existing lasers. With this laser, we are able to successfully achieve velocimetry of 40 m/s at a short distance of 0.4 m, with a measurable velocity up to the first cosmic velocity at 1 m away, that is inaccessible by conventional ranging approaches, and distance metrology with a ranging resolution of <2 cm. Moreover, for the first time to the best of our knowledge, we are able to realize a dramatically simplified architecture for laser frequency stabilization, by direct locking the laser to an external reference gas cell without any extra external light control. We successfully achieve a long-term laser stability with a frequency fluctuation of only $\pm$ 6.5 MHz over 60 minutes. The demonstrated Pockels laser combines elegantly high laser coherence with ultrafast frequency reconfigurability and superior multifunctional capability that we envision to have profound impacts on many areas including communication, sensing, autonomous driving, quantum information processing, and beyond.
title Pockels Laser Directly Driving Ultrafast Optical Metrology
topic Optics
url https://arxiv.org/abs/2410.07482