Title :
Highly phase stable mode-locked lasers
Author :
Fortier, Tara M. ; Jones, David J. ; Ye, Jun ; Cundiff, S.T.
Author_Institution :
Univ. of Colorado, Boulder, CO, USA
Abstract :
The authors report on stabilizing the carrier-envelope phase of mode-locked Ti:sapphire lasers. Optimization of the construction of the lasers for ease of phase stabilization is discussed. Results demonstrating long-term phase coherence of the generated pulse train are presented, yielding a phase coherence time of at least 326 s, measurement time limited. The conversion of amplitude noise to phase noise in the microstructured fiber, which is used to obtain an octave spanning spectrum, is measured. The resulting phase noise is found to be sufficiently small so as to not corrupt the phase stabilization. Shift of carrier-envelope phase external to the laser cavity due to propagation through a dispersive material is measured.
Keywords :
laser cavity resonators; laser feedback; laser mode locking; laser noise; optical harmonic generation; optical phase locked loops; optical pulse generation; phase noise; solid lasers; titanium; Al2O3:Ti; amplitude noise; carrier-envelope phase stabilization; external second harmonic crystal; frequency doubled; generated pulse train; highly phase stable lasers; laser cavity; long-term phase coherence; microstructured fiber; mode-locked Ti:sapphire lasers; octave spanning spectrum; optical frequency metrology; phase noise; self-referencing; Coherence; Fiber lasers; Laser mode locking; Laser noise; Laser stability; Optical pulse generation; Phase measurement; Phase noise; Pulse measurements; Time measurement;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2003.819110
