Title :
Modeling of Dy/sup 3+/-doped GeAsSe glass 1.3-μm optical fiber amplifiers
Author :
Schaafsma, D.T. ; Shaw, L.B. ; Cole, B. ; Sanghera, J.S. ; Aggarwal, D.
Author_Institution :
Naval Res. Lab., Washington, DC, USA
Abstract :
We present a model for optical amplification at 1.3 μm using Dy/sup 3+/ in fibers made from a low phonon energy glass, based on GeAsSe. This model uses in-band pumping at 1.28 μm, takes into account the spectral distribution of amplified spontaneous emission, and allows for bottlenecking of excited ions into the intermediate states in Dy as well as the excited state absorption (ESA) from those levels. Using data obtained from spectroscopic measurements and Judd-Ofelt calculations, our model shows that very high gain (>30 dB) is possible in short lengths (40-100 cm) of fiber. Given the very high quantum efficiency of the radiative transition in this glass, we show that bottlenecking and ESA should not have a significant impact on device performance. We also predict that devices made from this fiber should have a very high tolerance to the passive loss of the fiber.
Keywords :
dysprosium; excited states; fibre lasers; germanium compounds; infrared sources; laser theory; laser transitions; optical communication equipment; optical fibre losses; optical glass; optical pumping; 1.28 mum; 1.3 mum; 40 to 100 cm; Dy/sup 3+/-doped GeAsSe glass optical fiber amplifiers; GeAsSe:Dy; Judd-Ofelt calculations; amplified spontaneous emission; bottlenecking; device performance; excited ions; excited state absorption; in-band pumping; intermediate states; low phonon energy glass; optical communications equipment; passive fibre loss; radiative transition; spectral distribution; spectroscopic measurements; very high gain; very high quantum efficiency; very high tolerance; Absorption; Glass; Optical fiber amplifiers; Optical fiber communication; Optical fiber devices; Optical fibers; Optical materials; Phonons; Spectroscopy; Spontaneous emission;
Journal_Title :
Photonics Technology Letters, IEEE
