Quantum-dot semiconductor optical amplifiers for high-bit-rate signal processing up to 160 Gb s-1 and a new scheme of 3R regenerators

This paper presents a theory and simulation of quantum-dot semiconductor optical amplifiers (SOAs) for high-bit-rate optical signal processing. The theory includes spatial isolation of quantum dots, carrier relaxation and excitation among the discrete energy states and the wetting layer, grouping of dots by their optical resonant frequency under the inhomogeneous broadening, and the homogeneous broadening of the single-dot gain, which are all essential to the amplifier performance. We show that high-speed gain saturation occurs due to spectral hole burning under the optical pulse trains up to at least 160 Gb s-1 with negligible pattern effect, and that the self-assembled InGaAs/GaAs quantum-dot SOAs have about two to three orders faster response speed than bulk InGaAsP SOAs, with one order larger gain saturation for the 160 Gb s-1 signals. We also show that switching functions can be realized by the cross gain modulation between the two wavelength channels when the channel separation is within the homogeneous broadening. These results indicate great potential of quantum-dot SOAs for all-optical high-speed switches. As one of their possible applications, we propose a new signal-processing scheme of a `quantum-dot 3R regenerator'.

[1]  Alexander V. Uskov,et al.  Auger carrier capture kinetics in self-assembled quantum dot structures , 1998 .

[2]  S. Krishna,et al.  High-speed modulation and switching characteristics of In(Ga)As-Al(Ga)As self-organized quantum-dot lasers , 2000, IEEE Journal of Selected Topics in Quantum Electronics.

[3]  D. Bimberg,et al.  Ultrafast gain dynamics in InAs-InGaAs quantum-dot amplifiers , 2000, IEEE Photonics Technology Letters.

[4]  Haruhiko Kuwatsuka,et al.  Nonlinear gain dynamics in quantum-dot optical amplifiers and its application to optical communication devices , 2001 .

[5]  Hiroshi Ishikawa,et al.  Room-temperature gain and differential gain characteristics of self-assembled InGaAs/GaAs quantum dots for 1.1–1.3 μm semiconductor lasers , 2000 .

[6]  Hiroshi Ishikawa,et al.  Enhancement of third-order nonlinear optical susceptibilities in compressively strained quantum wells under the population inversion condition , 1999 .

[7]  Hiroshi Ishikawa,et al.  Effect of homogeneous broadening of optical gain on lasing spectra in self-assembled In x Ga 1-x As/GaAs quantum dot lasers , 2000 .

[8]  H. Ishikawa,et al.  Application of spectral-hole burning in the inhomogeneously broadened gain of self-assembled quantum dots to a multiwavelength-channel nonlinear optical device , 2000, IEEE Photonics Technology Letters.

[9]  M. Sugawara,et al.  Theoretical calculation of lasing spectra of quantum-dot lasers: effect of homogeneous broadening of optical gain , 2000, IEEE Photonics Technology Letters.

[10]  Hiroshi Ishikawa,et al.  Quantum-Dot Semiconductor Optical Amplifiers for High Bit-Rate Signal Processing over 40 Gbit/s , 2001 .

[11]  N. Olsson,et al.  Self-phase modulation and spectral broadening of optical pulses in semiconductor laser amplifiers , 1989 .

[12]  Saulius Marcinkevicius,et al.  Photoexcited carrier transfer in InGaAs quantum dot structures: Dependence on the dot density , 2000 .

[13]  T. W. Berg,et al.  Ultrafast gain recovery and modulation limitations in self-assembled quantum-dot devices , 2001, IEEE Photonics Technology Letters.

[14]  D. Bimberg,et al.  Spectral hole-burning and carrier-heating dynamics in quantum-dot amplifiers: comparison with bulk amplifiers , 2001 .