Concentration quenching and clustering effects in Er:YAG-derived all-glass optical fiber
A. Vonderhaar, Miranda P. Stone, J.H. Campbell, Thomas W. Hawkins, John Ballato, Peter D. Dragic
Abstract
A detailed investigation of concentration quenching and ion clustering effects in Er:YAG-derived all-glass optical fibers fabricated using the molten core method (MCM) is presented. Fibers are drawn from four precursor Er:YAG crystals, each possessing a different Er 3+ concentration. The resulting fibers exhibited active ion densities ranging from 2.58 × 10 25 m -3 to 19.5 × 10 25 m -3 . Compositional and refractive index profiles (RIPs) are shown to be uniformly graded across the fibers, for a given core diameter, facilitating the study of the impact of draw and host composition on rare earth spectroscopy, a first to the best of the Author’s knowledge. Measurements of the fluorescence lifetimes indicate some degree of clustering persists in all fibers; however, its reduction can clearly be correlated to an increase in sesquioxide (Al 2 O 3 and Y 2 O 3 ) concentration. Similarly, the critical quenching concentration is also revealed to increase with increasing sesquioxide concentration and ranged from 23.9 × 10 25 m -3 to 40.4 × 10 25 m -3 in the present fibers. Finally, emission and absorption spectra were found to be practically indistinguishable between the various fibers, with a zero-concentration radiative lifetime determined to be around 8.3 ms. Compared with other silica-based hosts, this lifetime is slightly lower, giving rise to proportionately higher cross-sections.