Radiative parameters for multi-channel visible and near-infrared emission transitions of Sm3+ in heavy-metal-silicate glasses

Multi-channel visible and near-infrared (NIR) emission transitions originating from 4G5/2 emitting state of Sm3+ in cadmium-aluminum-silicate (CAS) glasses with maximum-phonon-energy of ∼980 cm−1 have been investigated. Based on the measured absorption spectrum, the Judd–Ofelt parameters Ωt (t=2, 4, 6) are derived to be 2.87×10−20, 3.34×10−20 and 1.86×10−20 cm2, respectively. From the evaluated Judd–Ofelt parameters, the radiative parameters such as spontaneous emission probabilities (Arad), branching ratios (β), and radiative lifetime (τrad) are obtained from the 4G5/2 excited level to different lower energy levels. The efficient visible and NIR transition emissions have been observed in the Sm3+ doped CAS glasses, and the maximum stimulated emission cross-sections (σe-max) corresponding to emission peaks are calculated and demonstrated to lay in the same order of magnitude. The quantum efficiency of 4G5/2 level of Sm3+ has been derived to be 60%. Investigations on multi-channel radiative transition emissions originated from 4G5/2 level of Sm3+ in CAS glasses expose its potential applications in tunable laser, medical light source and NIR optoelectronic devices.

► Multi-channel transitions of Sm3+ in heavy-metal-silicate glasses are investigated.
► Judd–Ofelt parameters are derived to be 2.87×10−20, 3.34×10−20 and 1.86×10−20 cm2.
► Cross-section profiles σe for visible and NIR emissions are calculated by FL formula.
► σe-max values for NIR and visible emissions are almost in the same order of magnitude.
► Efficient multi-peak emissions indicate the potential in developing optical devices.