Title :
Enhanced multiwave mixing interactions in semiconductor optical amplifiers via pump modulation
Author_Institution :
Dept. of Phys., Imperial Coll., London, UK
fDate :
1/1/1992 12:00:00 AM
Abstract :
It is demonstrated that, by modulating a semiconductor optical amplifier at a frequency determined by the detuning between the pump and probe in a collinear four wave mixing geometry, the enhancements in gain and reflectivity of two to three orders of magnitude are possible for remarkably small modulation depths (m=10-2). The mechanism of frequency mixing using population pulsations in semiconductor laser amplifiers is summarized. In particular, the modification to the standard geometry to achieve enhancements is discussed. The appropriate four wave mixing equations including current modulation terms are solved analytically in the undepleted pump approximation. The analytic forms for transmission gain and phase conjugate reflectivity in several cases of interest are computed. In particular, the case in which four wave mixing is absent and energy transfer occurs solely as a result of the current modulation is examined
Keywords :
frequency modulation; laser theory; multiwave mixing; optical modulation; optical pumping; semiconductor junction lasers; collinear four wave mixing geometry; current modulation; energy transfer; four wave mixing equations; frequency mixing; frequency modulated diode lasers; laser gain enhancement; multiwave mixing interactions; optical modulation; phase conjugate reflectivity; population pulsations; pump modulation; pump/probe detuning; semiconductor optical amplifiers; small modulation depths; transmission gain; undepleted pump approximation; Four-wave mixing; Frequency; Geometrical optics; Multiwave mixing; Nonlinear optics; Optical mixing; Optical modulation; Reflectivity; Semiconductor optical amplifiers; Stimulated emission;
Journal_Title :
Quantum Electronics, IEEE Journal of
