Abstract
Photoluminescent mechanisms in erbium-doped barium titanate nanoparticle systems were studied. Er(3+) ions were introduced into the BaTiO₃ lattice by the sol-gel method. The resulting Er(3+) concentration was between 0% and 5%, with Ba/Ti ratios of 1.008 and 0.993. The stoichiometry of Ba and Ti concentrations in the lattice influenced the doping mechanism and placement of erbium ions in the lattice structure. Our research shows the existence of a strong correlation between Ba/Ti ratios, erbium concentration, phase structure and doping site location on the upconversion photoluminescence mechanisms. Competing upconversion emissions ²H(11/2)/⁴S(3/2)→⁴I(15/2) at 523 and 548 nm respectively and other photoluminescent mechanisms as ⁴I(9/2)→⁴I(11/2) around 4000 nm (2500 cm(-1)) were studied using Raman and emission spectroscopy. The upconversion process is predominant over other photoluminescent decay when the material presents high distortion in the surrounding activator.