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Large Raman gain and nonlinear phase shifts in high-purity As_2Se_3 chalcogenide fibers
376
Citations
22
References
2004
Year
Optical MaterialsEngineeringNonlinear OpticsLaser ApplicationsFiber OpticsHigh-power LasersFiber-optic CommunicationShort-pulse LasersNonlinear Phase ShiftsOptical AmplificationOptical PropertiesKerr Nonlinear CoefficientsOptical SolitonFiber LaserMaterials SciencePhotonicsPhysicsLarge Raman GainNon-linear OpticFiber OpticCondensed Matter PhysicsApplied PhysicsThird-order Kerr NonlinearitiesRaman GainFibre Amplifier
The study explores discrete Raman amplifiers and optical regenerators as potential applications. The authors experimentally investigate third‑order Kerr nonlinearities and Raman gain in high‑purity As₂Se₃ fibers at 1.55 µm. They find Kerr coefficients about 1000× silica, achieve ~1.2π‑rad phase shifts in 85‑cm fibers at 3 W, but incur ~20% loss at π shift, and observe Raman gains nearly 800× silica with cw pumping, though cw operation suffers index‑grating losses at the fiber exit.
Third-order Kerr nonlinearities and Raman gain are studied experimentally in high-purity As2Se3 optical fibers for wavelengths near 1.55 μm. Kerr nonlinear coefficients are measured to be nearly 1000 times higher than those for silica fibers. In pulsed mode, nonlinear phase shifts near 1.2-π rad are measured in fibers only 85 cm long with peak pulse powers near 3 W. However, there are nonlinear losses near 20% for nonlinear phase shifts near π. By use of a cw optical pump, large Raman gains nearly 800 times that of silica were measured. In the cw case there were losses in the form of index gratings formed from standing waves at the exit face of the fiber. Discrete Raman amplifiers and optical regenerators are discussed as possible applications.
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