UV and IR emission intensity in ZnO films, nanorods, and bulk single crystals doped with Er and additionally introduced impurities

For ZnO films, nanorods, and bulk single crystals doped with Er⁺ ions, it is shown that the effect of codopants introduced into the cation and ion sublattices and the observation of a high-intensity emission band at the wavelength λ_max = 1535 nm are defined by the local environment of the Er⁺ ion. Doping of the films and single crystals with Er⁺ ions by diffusion brings about an infrared (IR) emission band with a low intensity because of an inadequate concentration of impurity ions. The emission intensity of this band can be raised by introducing additional Ag, Au, or N⁺ impurities into the ZnO films. The UV-emission intensity of the Er-doped films and single crystals at λ_max = 368–372 nm is identical to that of the undoped films. ZnO nanorods doped with Er only or together with Al or Ga codopants exhibit only one IR band (at λ_max = 1535 nm), whose intensity decreases upon the introduction of codopants. Doping of the nanorods with the N⁺ gaseous impurity during growth (930 < T < 960°C) and then with the Er⁺ impurity by diffusion does not yield a substantial increase in the IR-emission intensity compared to the that of the corresponding band for nanorods not doped with the N⁺ impurity. In the Er-doped nanorods, whose photoluminescence spectra exhibit a high-intensity band at λ_max = 1535 nm, the UV emission band at λ_max = 372 nm is practically lacking.