Title :
Large Pitch Photonic Quasi-Crystal Fiber Amplifier
Author :
Sivabalan, S. ; Raina, J.P.
Author_Institution :
Sch. of Electr. Eng., VIT Univ., Vellore, India
fDate :
6/1/2012 12:00:00 AM
Abstract :
We design an ytterbium-doped large pitch photonic quasi-crystal fiber (PQF) for amplifying high-energy ultrashort laser pulses. The proposed fiber exhibits unique properties such as very large mode area (4660 μm2), less attenuation (0.42 dB/km), high overlapping factor (0.55 for the fundamental mode), and low bending loss. These properties help amplify with high-average power ultrashort pulses with less distortion and high efficiency. To meet these requirements, we design a fiber with optimum gain filtering as well as loss filtering. From the numerical simulation of the analytical model, we confirm that the large pitch PQF plays an indispensable role in amplifying high-energy ultrashort pulses.
Keywords :
holey fibres; laser modes; numerical analysis; optical design techniques; optical distortion; optical fibre amplifiers; optical fibre filters; optical fibre losses; photonic crystals; quasicrystals; ytterbium; PQF design; analytical model; fiber attenuation; fundamental mode; high overlapping factor; high-average power ultrashort pulses; high-energy ultrashort laser pulses; loss filtering; low bending loss; numerical simulation; optimum gain filtering; pulse distortion; very large mode area; ytterbium-doped large pitch photonic quasicrystal fiber amplifier; Attenuation; Frequency modulation; Indexes; Optical losses; Optical pulse generation; Photonics; Refractive index; Photonic quasi-crystal fibers (PQFs); chirped pulse amplification; fiber amplifier; large mode area fiber; ultrashort pulse amplifier;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2012.2201147
