Soliton self-frequency shift (SSFS), a consequence of Raman self-pumping
that continuously red-shifts a soliton pulse, has been widely studied
recently for applications to fiber-based sources and signal processing.
In this paper, the fundamentals of SSFS are reviewed. Various fiber
platforms for SSFS (single-mode fiber, microstructured fiber, and
higher order mode fiber) are presented and experimental SSFS demonstrations
in these fibers are discussed. Observation of Cerenkov radiation
in fibers exhibiting SSFS is also presented. A number of interesting
applications of SSFS, such as wavelength-agile lasers, analog-to-digital
conversion, and slow light, are briefly discussed.
%0 Journal Article
%1 Lee2008
%A Lee, J. H.
%A van Howe, J.
%A Xu, C.
%A Liu, Xiang
%B Selected Topics in Quantum Electronics, IEEE Journal of
%D 2008
%K (SSFS) Cerenkov Cherenkov Nonlinear Raman analog-to-digital conversion fiber fiber-based fibres higher lasers light microstructured mode optical optics order processing pulse pumping radiation red red-shifts self-frequency self-pumping shift signal single-mode slow soliton solitons sources tunable wavelength-agile
%P 713-723--
%T Soliton Self-Frequency Shift: Experimental Demonstrations and Applications
%V 14
%X Soliton self-frequency shift (SSFS), a consequence of Raman self-pumping
that continuously red-shifts a soliton pulse, has been widely studied
recently for applications to fiber-based sources and signal processing.
In this paper, the fundamentals of SSFS are reviewed. Various fiber
platforms for SSFS (single-mode fiber, microstructured fiber, and
higher order mode fiber) are presented and experimental SSFS demonstrations
in these fibers are discussed. Observation of Cerenkov radiation
in fibers exhibiting SSFS is also presented. A number of interesting
applications of SSFS, such as wavelength-agile lasers, analog-to-digital
conversion, and slow light, are briefly discussed.
@article{Lee2008,
abstract = {Soliton self-frequency shift (SSFS), a consequence of Raman self-pumping
that continuously red-shifts a soliton pulse, has been widely studied
recently for applications to fiber-based sources and signal processing.
In this paper, the fundamentals of SSFS are reviewed. Various fiber
platforms for SSFS (single-mode fiber, microstructured fiber, and
higher order mode fiber) are presented and experimental SSFS demonstrations
in these fibers are discussed. Observation of Cerenkov radiation
in fibers exhibiting SSFS is also presented. A number of interesting
applications of SSFS, such as wavelength-agile lasers, analog-to-digital
conversion, and slow light, are briefly discussed.},
added-at = {2009-11-19T14:40:48.000+0100},
author = {Lee, J. H. and van Howe, J. and Xu, C. and Liu, Xiang},
biburl = {https://www.bibsonomy.org/bibtex/251e6adbbf30752ca3705cad50d939132/photonics},
booktitle = {Selected Topics in Quantum Electronics, IEEE Journal of},
interhash = {1ced8be2cbc800e5c04ca6ffe3194d85},
intrahash = {51e6adbbf30752ca3705cad50d939132},
keywords = {(SSFS) Cerenkov Cherenkov Nonlinear Raman analog-to-digital conversion fiber fiber-based fibres higher lasers light microstructured mode optical optics order processing pulse pumping radiation red red-shifts self-frequency self-pumping shift signal single-mode slow soliton solitons sources tunable wavelength-agile},
owner = {gianluca},
pages = {713-723--},
refid = {486},
timestamp = {2009-11-19T14:40:57.000+0100},
title = {Soliton Self-Frequency Shift: Experimental Demonstrations and Applications},
volume = 14,
year = 2008
}