Title :
Mode locking by cascading of second-order nonlinearities
Author :
Zavelani-Rossi, M. ; Cerullo, G. ; Magni, V.
Author_Institution :
Dipt. di Fisica, Centro di Electr. Quantistica, Milan, Italy
fDate :
1/1/1998 12:00:00 AM
Abstract :
We present a comprehensive theoretical and experimental study on a new passive mode-locking technique, called cascaded second-order nonlinearity mode locking (CSM), which exploits cascaded second-order nonlinearities to obtain large third-order susceptibilities from an intracavity second harmonic crystal. The nonlinear phase shift that originates in the nonlinear crystal is converted into a nonlinear amplitude modulation by a suitable intracavity aperture. A numerical model, based on a perturbative approach, allows the nonlinear loss modulation of resonators used for CSM to be calculated as a function of the resonator parameters and of the phase mismatch. The predictions of the model are confirmed by experiments performed on a CW Nd:YAG laser. The effects of group velocity mismatch and the limitations which it poses on the minimum achievable pulsewidth are analyzed both experimentally and theoretically
Keywords :
laser cavity resonators; laser mode locking; neodymium; nonlinear optical susceptibility; optical harmonic generation; optical losses; optical modulation; optical pumping; perturbation techniques; solid lasers; CW Nd:YAG laser; YAG:Nd; YAl5O12:Nd; cascaded second-order nonlinearities; cascaded second-order nonlinearity mode locking; cascading; group velocity mismatch; intracavity aperture; intracavity second harmonic crystal; limitations; minimum achievable pulsewidth; mode locking; nonlinear amplitude modulation; nonlinear crystal; nonlinear loss modulation; nonlinear phase shift; numerical model; passive mode-locking technique; perturbative approach; phase mismatch; resonator parameters; resonators; second-order nonlinearities; third-order susceptibilities; Apertures; Laser mode locking; Laser noise; Laser theory; Mirrors; Optical beams; Optical frequency conversion; Optical pulses; Optical resonators; Solid lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
