Bismuth Oxide Nanoparticles Partially Substituted with EuIII, MnIV , and SiIV: Structural, Spectroscopic, and Optical Findings

Interest in nanostructured partially substituted bismuth oxides has been increasing over the last years. Research on new synthesis methods, properties, and possible uses for these oxides is needed. The objective of this paper is to synthesize beta-Bi2O3, beta-Bi2O3:Eu3+, beta-Bi2O3:Mn4+, Bi-12 Bi (0.8) O-19.2) Bi12Bi0.8O19.2/Li+; Bi12MnO20) and Bi12SiO20 nanoparticles and to investigate their structural, spectroscopic, and optical changes. Some of the causes that generated their properties are also discussed. These materials are important because the doping or partial substitution of bismuth oxide with these cations (Eu3+, Mn4+, and Si4+) modifies some properties such as optical absorption, reactivity toward CO2, among others. X-ray diffraction (in powders), high-resolution transmission electron microscopy, Fourier transform infrared (FTIR), resonance Raman scattering, diffuse reflectance, and solid-state magic -angle spinning Si-29 NMR were used for the characterization of the synthesized materials. We found that partial substitution of yellow Bi(12)Bi(0.8)O(19.)2 with Mn4+ and Si4+ changed the color to green and whitish, respectively. New bands in the Raman scattering and FTIR spectra of these oxides are deeply discussed. Raman scattering spectroscopy was a valuable and reliable technique to detect the Eu3+ and Mn4+ cations as dopants in the bismuth oxides. The Si-29 chemical shift (delta) in Bi12SiO20 was 78.16 ppm, whereas in SiO2, it was around -110 ppm. This considerable shift in Bi12SiO20 occurred because of an increased shielding of the Si nucleus in the Si(O)(4) tetrahedron. This shielding was provided by the low-electronegativity and highly polarizable Bi cations. The isovalent doping of fi-Bi203 nanoparticles with Eu3+ enhanced their thermal stability over 400(circle) . Variation in the optical absorption and reactivity toward the acidic CO, molecule of the partially substituted bismuth oxides was explained on the basis of the optical basicity and ionic covalent parameter concepts. Some possible uses for the synthesized oxides are suggested.