Cover Image

Structural and vibrational spectroscopic studies of new phases with sillenite type in the system Bi2O3- In2O3 –MgO

Hajar Ait Oulahyane, Abdeslam Chagraoui, Leila Loubbidi, Lamia Bourja, Omar Ait Sidi Ahmed, Abdelmjid Tairi

Abstract


The anion and cation deficient phase Bi0.95 In0.05 O1.5 (Bi1.9 In0.1 O3) was synthesized and experimentally investigated using X-ray diffraction and vibrational spectroscopy (Infrared and Raman). The non-stoichiometric phases are similar to sillenite family type γBi2O3 and crystallize in the I23 space group. The crystal structure was determined by full profile Rietveld analysis of the powder diffractogram. It is formed by a sequence of BiO5E polyhedra (E lone pair of bismuth) and MO4 polyhedra (M = In, Mg). The set of MO4 polyhedra are localized in cavities generated by BiO5E polyhedra. The vibrational spectroscopic study revealed the existence of three regions; low, intermediate and high-frequency region. They are attributed to Bi-O stretching mode, In / Mg-O vibrations and cationic displacements respectively.


Full Text:

PDF

References


- S. Iyyapushpam, S. T. Nishanthi, D. Pathinettam Padiyan, Enhanced photocatalytic degradation of methyl orange by gamma Bi2O3 and its kinetics, J Alloys Compd, 2014, 601, 85–87.

- S. Y. Chai, Y. J. Kim, M. H. Jung, A. K. Chakraborty, D. Jung, W. I. Lee, Heterojunctioned BiOCl/Bi2O3, a new visible light photocatalyst, J Catal, 2009, 262, 144–149.

- J. Zeng, J. Li, J. Zhong, S. Huang, W. Shi, J. He, Synthesis, characterization and solar photocatalytic performance of In2O3-decorated Bi2O3, Mater Sci Semicond Process, 2013, 16, 1808–1812.

- J. Eberl, H. Kisch, Visible light photo-oxidations in the presence of α-Bi2O3, Photochem Photobiol Sci, 2008, 7, 1400.

- H.-Y. Jiang, K. Cheng, J. Lin, Crystalline metallic Au nanoparticle-loaded α-Bi2O3 microrods for improved photocatalysis, Phys Chem Chem Phys, 2012, 14, 12114.

- Z. Ai, Y. Huang, S. Lee, L. Zhang, Monoclinic α-Bi2O3 photocatalyst for efficient removal of gaseous NO and HCHO under visible light irradiation, J Alloys Compd, 2011, 509, 2044–2049.

- I. F. Vasconcelos, M. A. Pimenta, A. S. B. Sombra, Optical properties of Bi12SiO20 (BSO) and Bi12TiO20 (BTO) obtained by mechanical alloying, J Mater Sci, 2001, 36, 587–592.

- M. Mesrar, T. Lamcharfi, N.-S. Echatoui, F. Abdi, F. Z. Ahjyaje, M. Haddad, Effect of barium doping on electrical and electromechanical properties of (1-x)(Na0.5Bi0.5)TiO3-xBaTiO3, MediterrJChem, 2019, 8, 198.

- H. AitOulahyane, L. Loubbidi, A. Chagraoui, L. Bourja, S. Villain, O. Ait Sidi Ahmed, A. Moussaoui, A. Menichi, Structural, Electrical and Morphological Properties of Materials Type Sillenite Phase Bi12TiO20, Chemistry Africa, 2019, 2, 57–66.

- E. M. Levin, R. S. Roth, Polymorphism of bismuth sesquioxide. II. Effect of oxide additions on the polymorphism of Bi2O3, J Res Natl Bur Stan Sect A, 1964, 68A, 197.

- S. F. Radaev, V. I. Simonov, Yu. F. Kargin, Structural features of γ-phase Bi2O3 and its place in the sillenite family, Acta Crystallogr B Struct Sci, 1992, 48, 604–609.

- S. F. Radaev, L. A. Muradyan, V. I. Simonov, Atomic structure and crystal chemistry of sillenites: Bi12(Bi3+0.50Fe3+0.50)O19.50 and Bi12(Bi3+0.67Zn2+0.33)O19.33, Acta Crystallogr B Struct Sci, 1991, 47, 1–6.

- M. Valant, D. Suvorov, A Stoichiometric Model for Sillenites, Chem Mater, 2002, 14, 3471–3476.

- A. Watanabe, S. Takenouchi, P. Conflant, J.-P. Wignacourt, M. Drache, J.-C. Boivin, Preparation of a Nonstoichiometric Sillenite-Type Phase in the System Bi2O3-As2O5, Journal of Solid State Chemistry, 1993, 103, 57–62.

- T. H. Noh, S. W. Hwang, J. U. Kim, H. K. Yu, H. Seo, B. Ahn, D. W. Kim, I. S. Cho, Optical properties and visible-light-induced photocatalytic activity of bismuth sillenites (Bi12XO20, X = Si, Ge, Ti), Ceram Int, 2017, 43, 12102–12108.

- S. F. Radaev, V. I. Simonov, Y. F. Kargin, V. M. Skorikov, New data on structure and crystal chemistry of sillenites Bi12MxO20±δ, Eur J Solid State Inorg Chem, 1992, 29, 383–392.

- J.-C. Champarnaud-Mesjard, B. Frit, A structural model for the Bi1−xCdxO1.5−x/2 (0 ≤ x ≤ 0.0256) sillenite-type solid solution, C R Acad Sci Paris, t 2, Série II c, 1999, 2, 369–374.

- Program Full Prof.2k (Version 5.30 - Mar2012-ILL JRC).

- Y. Hu, D. C. Sinclair, Relaxor-like Dielectric Behavior in Stoichiometric Sillenite Bi 12 SiO20, Chem Mater, 2013, 25, 48–54.

- R. D. Shannon, Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides, Acta Cryst A, 1976, 32, 751–767.

- V. I. Burkov, V. S. Gorelik, A. V. Egorysheva, Y. F. Kargin, Laser Raman Spectroscopy of Crystals with the Structure of Sillenite, J Russ Laser Res, 2001, 22, 25.

- A. V. Egorysheva, V. I. Burkov, Y. F. Kargin, V. G. Plotnichenko, V. V. Koltashev, E. D. Obraztsova, S. V. Terekhov, Atomic Structure Features of Sillenite Crystals as Probed by Raman Spectroscopy, Russ J Inorg Chem, 2005, 50, 238–245.

- I. J. Panneerdoss, S. J. Jeyakumar, S. Ramalingam, M. Jothibas, Characterization of prepared In2O3 thin films: The FT-IR, FT-Raman, UV–Visible investigation and optical analysis, Spectrochim Acta, Part A, 2015, 147, 1–13.

- B. Mihailova, M. Gospodinov, L. Konstantinov, Raman spectroscopy study of sillenites. I. Comparison between Bi12(Si, Mn)O20 single crystals, Journal of Physics and Chemistry of Solids, 1999, 60, 1821–1827.

- X. Zhu, J. Zhang, F. Chen, Study on visible light photocatalytic activity and mechanism of spherical Bi12TiO20 nanoparticles prepared by low-power hydrothermal method, Applied Catalysis B: Environmental, 2011, 102, 316–322.

- Zs. Szaller, L. Kovács, L. Pöppl, Comparative Study of Bismuth Tellurites by Infrared Absorption Spectroscopy, J Solid State Chem, 2000, 152, 392–396.




DOI: http://dx.doi.org/10.13171/mjc101020011123hao

Refbacks

  • There are currently no refbacks.


Copyright (c) 2020 Mediterranean Journal of Chemistry