DocumentCode
909648
Title
High-spectral purity RF beat note generated by a two-frequency solid-state laser in a dual thermooptic and electrooptic phase-locked loop
Author
Brunel, M. ; Bretenaker, F. ; Blanc, S. ; Crozatier, V. ; Brisset, J. ; Merlet, T. ; Poezevara, A.
Author_Institution
Lab. de Phys. des Lasers, Univ. de Rennes I-CNRS, France
Volume
16
Issue
3
fYear
2004
fDate
3/1/2004 12:00:00 AM
Firstpage
870
Lastpage
872
Abstract
Ultralow noise stabilization of a two-frequency solid-state laser is experimentally demonstrated using a specially designed dual phase-locked loop. Thanks to an intracavity birefringent crystal providing both thermooptic and electrooptic frequency modulation properties, the laser delivers a beat frequency that is controlled by both pump power and voltage from 0 to 1000 MHz. When phase-locked against a radio-frequency synthesizer, the beat note has a 25-mHz full-width at half-maximum. The measured phase noise is -110 dBc/Hz at 10-kHz offset, and lower than -130 dBc/Hz at 1-MHz offset and above. Improvements and applications to local oscillators in microwave-photonic systems are discussed.
Keywords
birefringence; electro-optical effects; electro-optical modulation; laser cavity resonators; laser frequency stability; laser mode locking; laser noise; microwave generation; microwave photonics; optical materials; optical phase locked loops; phase noise; solid lasers; thermo-optical devices; thermo-optical effects; 0 to 1000 MHz; beat frequency; beat note; dual phase-locked loop; dual thermooptic phase-locked loop; electrooptic frequency modulation properties; electrooptic phase-locked loop; high-spectral purity RF beat note; intracavity birefringent crystal; local oscillators; microwave-photonic systems; phase noise; pump power; radio-frequency synthesizer; thermooptic frequency modulation properties; two-frequency solid-state laser; ultralow noise stabilization; Birefringence; Frequency modulation; Laser noise; Lasers and electrooptics; Optical design; Phase locked loops; Phase noise; Power lasers; Radio frequency; Solid lasers;
fLanguage
English
Journal_Title
Photonics Technology Letters, IEEE
Publisher
ieee
ISSN
1041-1135
Type
jour
DOI
10.1109/LPT.2004.823757
Filename
1269823
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