The doping of nanoporous glass (PG) is a prospective technique for producing bismuth (Bi)-doped optical fibers. The refractive index of sintered PG is lower than pure silica glass because of PG high residual content of boron (2 to 3 at.%). This fact impedes the choice of fiber cladding for building a light-guiding structure. We have chosen the microstructured optical fiber with the core from Bi-doped nanoporous glass to overcome this problem. We have studied the glass composition and controlled the luminescent properties of bismuth active centers at each step of the fiber fabrication. The PG is suitable for the production of microstructured fibers.
In this paper, we performed numerical and experimental study of the stability of bismuth-doped high-GeO2 glass core fiber used as an active medium in lasers operating in the wavelength region 1600 - 1800 nm. Mainly, we focus on the investigation of the joint effects of temperature and pumping radiation on the spectroscopic and laser characteristics of the fibers. Temporal evolution of the degradation of bismuth-related active centers (BACs) under pumping at 1550 nm, as well as the annealing of the fibers at temperature ranging from 300 to 550 °C was experimentally revealed and studied. A model describing the photochemical processes of the transformation of the BACs at different ambient conditions was proposed and used to make a long-term prediction of the dynamics of the process. The ability to simulate the long-term behavior of the medium might be instrumental since direct measurements are time consuming and therefore impractical. In addition, we performed numerical simulation to find out how the effect of photoinduced degradation of BACs affects the performance of a laser based on this type of fibers.
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