The effect of Nd2O3 on the structure and spectroscopic properties of SrO-ZnO-P2O5 glass for NIR emission at 1.058 μm

Strontium zinc phosphate glasses containing neodymium ions were prepared. The current glasses show the presence of phosphate groups in the Q2 mode, overlapping with the vibration of Zn-O and Sr-O bonds. The glass density increased from 3.058 g/cm3 (the base glass) to 3.115 g/cm3 (the 1.5-Nd sample) as SrO was replaced with Nd2O3. The optical transition is known as an indirect transition, and the values ranged from 4.022 eV for the base sample to 3.572 eV for the 1.5-Nd sample. The Ravindra model correlates experimental refractive index data with optical band gap. Because of the presence of Nd2O3 in the current glass, distinct spectral absorption peaks are detected in the absorption spectra, which are analyzed using the modified Axe model for the Judd-Ofelt theory. The emission spectra show distinct emission peaks, which are suggested for the possible emission of NIR lasers at 0.9 mu m, and 1.058 mu m.

Automated summary

Strontium zinc phosphate glasses containing neodymium ions were prepared. The presence of phosphate groups in the Q2 mode overlapping with Zn-O and Sr-O bonds was observed in the current glasses. The replacement of SrO with Nd2O3 increased the glass density. The optical transition was found to be an indirect transition with varying values. The absorption spectra showed distinct peaks due to the presence of Nd2O3, and the emission spectra suggested possible emission of NIR lasers at specific wavelengths.