Pr3+- and Pr3+/ Er3+-Doped Selenide Glasses for Potential 1.6 mm Optical Amplifier Materials

Abstract

1.6 µm emission originated from Pr3+: (3F3, 3F4) → 3H4 transition in Pr3+- and Pr3+/Er3+-doped selenide glasses was investigated under an optical pump of a conventional 1480 nm laser diode. The measured peak wavelength and full-width at half-maximum of the fluorescent emission are ~1650 nm and ~120 nm, respectively. A moderate lifetime of the thermally coupled upper manifolds of ~212 ± 10 µs together with a high stimulated emission cross-section of ~(3 ± 1)×10−−20 cm2 promises to be useful for 1.6 µm band fiber-optic amplifiers that can be pumped with an existing high-power 1480 nm laser diode. Codoping Er3+ enhances the emission intensity by way of a nonradiative Er3+: 4I13/2 → Pr3+: (3F3, 3F4) energy transfer. The Dexter model based on the spectral overlap between donor emission and acceptor absorption describes well the energy transfer from Er3+ to Pr3+ in these glasses. Also discussed in this paper are major transmission loss mechanisms of a selenide glass optical fiber.