Mechanisms of Dual-Band Emission in Sb-Doped Rare-Earth Phosphates Revealed
Abstract
The Sb3+ ion has garnered significant interest due to its effectiveness in boosting the optical properties of host materials. Among the interesting phenomena is the commonly observed dual-band emission, which has often been interpreted by adopting the phenomenological model that explains the dual-band emission (``ultraviolet band'' and ``visible band'') in Sb-doped LPO4 (L = Sc, Y, Lu). However, the model for Sb-doped LPO4 series itself has not been well understood theoretically. In this work, we employ first-principles calculations combined with group-theory analysis to clarify the underlying physical mechanism behind dual-band emission in Sb-doped LPO4 series. We demonstrate that the dual-band arises from two excited-state equilibrium structures, one exhibits a relatively small distortion with respect to the ground-state equilibrium structure, while the other displays a significantly larger distortion, characteristic of an ``off-center'' configuration. The deviations from the ground-state configuration are dominated by two distinct vibrational modes, b2 and e modes, involving the Jahn-Teller effect and the pseudo Jahn-Teller effect, respectively. Furthermore, charge transition levels and energy barriers calculated using the climbing image nudged elastic band (CI-NEB) method have aided in understanding the relaxation between the two excited-state configurations and the property changes across the Sc, Y, and Lu series. These insights provide a basis for understanding the exotic properties of Sb3+ in other hosts and may facilitate the design of optical materials in a broader range of systems involving Sb3+ ions.
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