(163o) Tunable Luminescence of Rare Earth Doped Nanophosphors Via Adaptive Absorption of Transition Metals

Owing to their multifunctionality, chemical stability, and strong optical responses, TiO₂:Ni²⁺ thin films, synthesized via dopant-location controlled sol-gel chemistry, were chosen as the prototypical system for TM doped hosts. The surface of these films was functionalized with surface dipoles to engineer the interfacial energetics. Since these dipoles primarily act at the surface, surface-sensitive X-ray and UV spectroscopic techniques were employed to probe the changes in the electronic and geometric structure of the inorganic film. Additionally, these results were corroborated with first-principles simulations to elucidate the dipole-dopant interactions and deduce a quantitative relationship between the dipole moment and the change in the optoelectronic properties of TiO₂:Ni²⁺. As a proof-of-concept, the photoluminescence spectra of the RE doped core (NaYF₄:Er³⁺) with TM doped shell layer (TiO₂:Ni²⁺) showed an enhancement in the emission intensity of the Er³⁺, suggesting energy transfer between the Er³⁺-Ni²⁺ ions. Further, surface functionalization of these core-shell nanoparticles demonstrated adaptive absorption of Ni²⁺, indicating potentiality for dynamic luminescence. Ultimately, these tunable luminescent nanophosphors will reduce the RE dependence in clean energy technologies, especially LED lighting.