Title :
Nonlinear interactions of optical pulses in slow-mode nanowires
Author :
Dubreuil, Nicolas ; Baron, Alexandre ; Kroeger, Felix ; Trebaol, Stéphane ; Delaye, Philippe ; Frey, Robert ; Agrawal, Govind P.
Author_Institution :
Lab. Charles Fabry de l´´Inst. d´´Opt., Univ Paris-Sud, Palaiseau, France
Abstract :
Slow-mode micro-structured waveguides enable a large enhancement of optical nonlinearities. Using a generalization of the local field factor theory of nonlinear homogeneous media, we review the impact of the group velocity reduction on the hierarchy of the semi-conductor nonlinearities. As an illustration, we experimentally and theoretically reported an intrinsic limitation concerning the Raman amplification of short pulses in silicon nanowires through the self-phase modulation induced by both the optical Kerr effect and free-carrier refraction. Hence, we provide a fundamental insight on the nonlinear interaction of short pulses for the design of future slow-mode devices.
Keywords :
Raman spectra; amplification; elemental semiconductors; light refraction; micro-optics; nanophotonics; nanowires; optical Kerr effect; optical waveguides; self-phase modulation; silicon; Raman amplification; Si; free-carrier refraction; group velocity reduction; local field factor theory; nonlinear homogeneous media; nonlinear interactions; optical Kerr effect; optical nonlinearities; optical pulses; self-phase modulation; semiconductor nonlinearities; silicon nanowires; slow-mode devices; slow-mode microstructured waveguides; slow-mode nanowires; Approximation methods; Frequency measurement; Harmonic analysis; Optical amplifiers; Optical pumping; Optical variables measurement; Optical waveguides; Raman scattering; nonlinear optics; nonlinear slow-mode waveguide; self-phase modulation;
Conference_Titel :
Transparent Optical Networks (ICTON), 2011 13th International Conference on
Conference_Location :
Stockholm
Print_ISBN :
978-1-4577-0881-7
Electronic_ISBN :
2161-2056
DOI :
10.1109/ICTON.2011.5971134
