Title :
Ultralow Noise, Etalon Stabilized, 10-GHz Optical Frequency Comb Based on an SCOW Amplifier
Author :
Davila-Rodriguez, Josue ; Ozdur, Ibrahim T. ; Bagnell, Marcus ; Delfyett, Peter J. ; Plant, Jason J. ; Juodawlkis, Paul W.
Author_Institution :
CREOL, Univ. of Central Florida, Orlando, FL, USA
Abstract :
A slab-coupled optical waveguide amplifier (SCOWA) is used to construct a 10-GHz harmonically modelocked laser with an intra-cavity etalon that serves as a high-finesse spectral filter. The laser output is a frequency comb that is actively stabilized to the transmission peaks of the etalon through a Pound-Drever-Hall scheme. The linewidth of the individual comb-lines is ~1 kHz and the frequency instability <;300 kHz over 60 s. The output power exceeds 20 mW due to the high saturation power of the SCOWA. The residual timing jitter of the pulse-train is ~1.9 fs (1 Hz to 100 MHz). A much broader comb (~10 nm) is generated after dispersion compensation of the cavity and the output pulses are compressible to <;1 ps. A comparison of the timing jitter of the all-anomalous dispersion and dispersion compensated cavities is presented along with a previous result with a similar architecture.
Keywords :
laser beams; laser cavity resonators; laser frequency stability; laser mode locking; laser noise; light interferometers; optical fibre amplifiers; optical fibre couplers; optical fibre dispersion; optical fibre filters; optical pulse compression; optical pulse generation; optical saturation; spectral line breadth; timing jitter; Pound-Drever-Hall scheme; SCOW amplifier; comb-line linewidth; dispersion compensation; frequency 1 Hz to 100 MHz; frequency 10 GHz; frequency instability; harmonically mode-locked laser; high saturation power; high-finesse spectral filter; intracavity etalon; laser output frequency; laser output power; light transmission; output pulse compression; pulse-train; residual timing jitter; slab-coupled optical waveguide amplifier; ultralow noise etalon stabilized optical frequency comb; Cavity resonators; Dispersion; Laser mode locking; Laser noise; Optical noise; Optical pulses; Mode-locked lasers; ultralow-noise pulse-trains;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2012.2223814
