Abstract

We present spectroscopic evidence for the formation of tightly bound ${\text{Nd}}^{3+}$ clusters in chalcogenide glasses in which ${\text{Nd}}^{3+}$ ions are so close that no appreciable fluorescence is observed. According to a theoretical calculation using the rate-equation modeling and comparison with experimental results, this type of cluster contributes as the main source of energy transfer among ${\text{Nd}}^{3+}$ ions in Ga-free glasses, resulting in the strong fluorescence quenching. It is proposed that the total volume of such ${\text{Nd}}^{3+}$ clusters sharply decreases with Ga doping, while the spatial distance among ${\text{Nd}}^{3+}$ ions in clusters remains close enough for there to be no detectable fluorescence from these clustered ${\text{Nd}}^{3+}$ ions. Such clusters are then completely dissolved in glasses once a critical Ga concentration is reached.