Title :
Amplification properties of Er3+-doped photonic crystal fibers
Author :
Cucinotta, Annamaria ; Poli, Federica ; Selleri, Stefano ; Vincetti, Luca ; Zoboli, Maurizio
Author_Institution :
Dipt. di Ingegneria dell´´Informazione, Univ. di Parma, Italy
fDate :
3/1/2003 12:00:00 AM
Abstract :
The amplification properties of different photonic crystal fibers have been studied by means of a full vector finite-element modal formulation combined with a population and propagation rate equation solver. A honeycomb as well as a cobweb photonic crystal fiber have been considered. The consequences of the defect dimension and the dopant radius on the field intensity distribution as well as the overlap integrals have been analyzed. Results demonstrate that a proper photonic crystal fiber design can be usefully exploited in order to obtain active fibers with superior characteristics compared to standard step index ones. In particular, photonic crystal fibers open up the possibility of a gain medium with highly flexible geometric, dispersion, and amplifying characteristics.
Keywords :
erbium; finite element analysis; integral equations; optical fibre amplifiers; optical fibre dispersion; optical fibre theory; photonic crystals; vectors; Er3+-doped photonic crystal fiber amplifiers; Er3+-doped photonic crystal fibers; amplification properties; amplifying characteristics; cobweb photonic crystal fiber; defect dimension; dispersion characteristics; dopant radius; field intensity distribution; full vector finite-element modal formulation; gain medium; highly flexible geometric; honeycomb photonic crystal fiber; photonic crystal fiber design; population rate equation solver; propagation rate equation solver; Equations; Erbium; Erbium-doped fiber lasers; Finite element methods; Holey fibers; Laser modes; Optical control; Optical fiber devices; Photonic crystal fibers; Pump lasers;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2003.809576
