Title :
Measurement of self- and cross-gain saturation dynamics using two-color heterodyne pump-probe technique
Author :
Katayama, Takeo ; Kawaguchi, Hitoshi
Author_Institution :
Dept. of Electr. Eng., Yamagata Univ., Japan
fDate :
6/1/2005 12:00:00 AM
Abstract :
The gain dynamics of a symmetrical multiple-quantum-well semiconductor optical amplifier (SOA) with wide gain-bandwidth are measured by a two-color heterodyne pump-probe technique. Short optical pulses are generated by using optical filters to select spectral components from compressed supercontinuum optical pulses. To maintain durations of the order of 100 fs over the entire gain bandwidth of the SOA, the pulse broadening caused by frequency shifters is compensated by fibers with lengths optimized for respective wavelengths. We measure the wavelength dependences of the recovery time of carrier heating (CH) and the gain reduction due to CH. The gain reduction caused by spectral hole burning is observed.
Keywords :
laser variables measurement; optical fibre dispersion; optical filters; optical hole burning; optical phase shifters; optical pulse compression; optical pulse generation; optical saturation; quantum well lasers; semiconductor optical amplifiers; spectral line broadening; supercontinuum generation; 100 fs; carrier heating; compressed optical pulses; cross-gain saturation dynamics; frequency shifters; gain reduction; group velocity dispersion optical fiber; heterodyne pump-probe technique; optical filters; pulse broadening; recovery time; self-gain saturation dynamics; semiconductor optical amplifier; short optical pulses; spectral components; spectral hole burning; supercontinuum optical pulses; symmetrical multiple-quantum-well SOA; two-color pump-probe technique; wide gain-bandwidth; Bandwidth; Frequency; Gain measurement; Optical filters; Optical pulse generation; Optical pulses; Pulse amplifiers; Quantum well devices; Semiconductor optical amplifiers; Supercontinuum generation; Optical pulse compression; semiconductor optical amplifiers (SOAs); supercontinuum (SC) generation; ultrafast measurements;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2005.846562
