Open AccessOptical frequency distribution using laser repeater stations with planar lightwave circuits
Author(s) -
Tomoya Akatsuka,
Takashi Goh,
Hiromitsu Imai,
Katsuya Oguri,
Atsushi Ishizawa,
Ichiro Ushijima,
Noriaki Ohmae,
Masao Takamoto,
Hidetoshi Katori,
Toshikazu Hashimoto,
Hideki Gotoh,
Tetsuomi Sogawa
Publication year - 2020
Publication title -
optics express
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.394
H-Index - 271
ISSN - 1094-4087
DOI - 10.1364/oe.383526
Subject(s) - repeater (horology) , optics , optical link , laser , electronic circuit , bandwidth (computing) , optical fiber , computer science , physics , electronic engineering , telecommunications , electrical engineering , engineering , artificial intelligence , encoding (memory)
We report a cascaded optical fiber link which connects laboratories in RIKEN, the University of Tokyo, and NTT within a 100-km region using a transfer light at 1397 nm, a subharmonic of the Sr clock frequency. The multiple cascaded link employing several laser repeater stations benefits from a wide feedback bandwidth for fiber noise compensation, which allows constructing optical lattice clock networks based on the master-slave configuration. We developed the laser repeater stations based on planar lightwave circuits to significantly reduce the interferometer noise for improved link stability. We implemented a 240-km-long cascaded link in a UTokyo-NTT-UTokyo loop using light sent from RIKEN via a 30-km-long link. In environments with large fiber noise, the link instability is 3 × 10 -16 at an averaging time of 1 s and reaches 1 × 10 -18 at 2,600 s.
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