Structural and optical properties of Y, Cu co-doped ZnO nanoparticles by sol–gel method

• Zn.96−xY.04CuxO nanoparticles from Cu = 0–15% were successfully synthesized.
• Change in crystal size was discussed by stress, lattice volume and bond length.
• Oxygen rich phase after Cu = 5% was confirmed by XRD and EDX.
• Presence of Cu in ZnYO lattice was explained by peak position shift from FTIR.

Zn.96−xY.04CuxO (x = 0, 0.05, 0.10 and 0.15) nanoparticles were successfully synthesized employing simple sol–gel method. Hexagonal wurtzite structure of the synthesized samples was not affected by Cu-doping. CuO phase was induced after Cu = 5% and it was increased by Cu-doping. The change in crystal size was discussed based on compressive stress, lattice volume and bond length. The chemical stoichiometry of Zn, Cu, Y and O was confirmed by energy dispersive X-ray spectra. The increased oxygen percentage from 57.88 (Cu = 5%) to 64.53% (Cu = 15%) by Cu-doping proved the existence of CuO and oxygen rich phase. The lower absorption and high transmittance in visible region observed at Cu = 5% described the good optical quality of the sample with low scattering or absorption losses which leads to the industrial applications especially as transparent electrode. The high energy gap at Cu = 5% could be attributed to the poor crystallinity of the sample. The red shift in energy gap after Cu = 5% was explained by the p–d spin-exchange interactions between the band electrons and the localized d electrons of Cu2+ ions. The change in intensity and peak position of infrared (IR) peaks confirmed the presence of Cu in ZnYO lattice and also expressed the perturbation generated by Cu in ZnYO lattice.

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