Sol-gel synthesis, characterization, optical properties and catalytic performance of Y2Ce2O7 nanomaterial

Document Type : Reasearch Paper

Authors

1 Department of Chemistry, Science and Research Branch, Islamic Azad University, Tehran, Iran.

2 Department of Chemistry, Naragh Branch, Islamic Azad University, Naragh, Iran.

Abstract

Y2Ce2O7 nano powders were synthesized via sol-gel reactions at 900 (S1), 1000 (S2) and 1100 (S3) ˚C for 4 h using yttrium acetate (C6H9O6Y.xH2O), ammonium cerium nitrate ((NH4)2Ce(NO3)6) and stearic acid (C18H36O2) as raw materials at stoichiometric 1:1 Y:Ce molar ratio. The synthesized materials were characterized by powder X-ray diffraction (PXRD) technique and Fourier transforms infrared (FTIR) spectroscopy. Structural analysis was performed by the FullProf program employing profile matching with constant scale factors. The results showed that the patterns had a main cubic Y2Ce2O7 structure with space group of Fm3m. The data showed that the lattice parameters were increased with increasing the reaction temperature. FESEM images showed that the synthesized Y2Ce2O7 particles had mono-shaped sphere morphologies. However, with increasing the reaction temperature to 1100 ˚C, the particle size scale was in micrometre range. Ultraviolet–visible spectra analysis showed that the nanostructured Y2Ce2O7 powder (S2) possessed strong light absorption property in the ultraviolet light region. The direct optical band gap was calculated as 3.15 eV. Besides, the photoluminescence spectrum for the obtained material (S2) was investigated at λex=230 nm as excitation wavelength. It showed a strong emission peak at 425 nm. Catalytic performance of the synthesized nanomaterial (S2) was also investigated in alcohol oxidation reactions which showed excellent efficiency as 75%.

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References

[1] Sharma N., Subba Rao G. V., Chowdhuri B. V. R., (2006), Anodic properties of tin oxides with pyrochlore structure for lithium ion batteries. J. Power Sources. 159: 340–344.
[2] Mandal B. P., Garg N., Sharma S. M., Tyagi A. K., (2006), Preparation, XRD and Raman spectroscopic studies on new compounds RE2Hf2O7 (RE= Dy, Ho, Er, Tm, Lu, Y): Pyrochlores or defect-fluorite?. J. Solid State Chem. 179: 1990–1994.
[3] Li  T., Zhang K., Wang H., Yan H., (2006), Low-temperature synthesis and structure characterization of the serials Y2-δBiδSn2O7 () nanocrystals. J. Solid State Chem. 179: 1029–1034.
[4] Zhu H. L., Yang D. R., Zhu L. M., Li  D. S., Chen P. H., Yu G. X., (2007), Hydrothermal synthesis and photoluminescence properties of La2−xEuxSn2O7 (x=0–2.0) nanocrystals. J. Am. Ceram. Soc. 90: 3095–3098.
[5] Sickafus K. E., Minervini L., Grimes  R. W., Valdez J. A., Ishimaru M., Li F., McClellan K. J., Hartmann T., (2000), Radiation tolerance of complex oxides. Science. 289: 748–751.
[6] Sellami M., Caignaert V., Hamdad M., Belarbi A., Sari-Mohamed I., Bahmani A., Bettahar N., (2011), Synthesis and characterization of the new pyrochlore Bi1.5Sb1.5-xNbxMnO7. Solid Solution. C. R. Chimie. 14: 887–890.
[7] Raj A. K. V., Prabhakar R. P., Sreena T. S., Sameera S., James V., Renju U. A., (2014), Remarkable changes in the photo luminescent properties of Y2Ce2O7: Eu3+ red phosphors through modification of the cerium oxidation states and oxygen vacancy ordering. Phys. Chem. Chem. phys. 2014: 23699-23706.
[8] Momeni Larimi Z., Amir abadizadeh A., Zelati A., (2011), Synthesis of Y2O3 nanoparticles by modified transient morphology method. Int. Conf. Chem. Chem. Proc.  
[9] Enhessari M., Ozaee K., Shaterian M., Karamali E., (2013), Strontium cerate nanoparticle synthesis method. Pub. No.: US8512654 B2.
[10] Enhessari M., (2013), Synthesis, characterisation and optical band gap of Cr1.3Fe0.7O3 nanopigments. Pigm. Resin. Technol. 42: 347-352.
[11] Honghui J., Weixiong Y., Xiaolin L., Jinsheng L., Ping W., Bin Y., (2013), 𝑌𝑏+3 and 𝐸𝑟+3 co-doped 𝑌2𝐶𝑒2𝑂7 nanoparticles: Synthesis and spectroscopic properties. Bullet. Mater. Sci. 36: 1147-1151.
[12] Miller  F. A.,Wilkins  C. H., (1952), Infrared spectra and characteristic frequencies of inorganic ions. Anal.Chem. 24: 1253-1294.
[13] Sheibley D. W., Fowler M. H., (1966), Infrared spectra of various metal oxides in theregion of 2 to 26 microns. nasatn d-3750. Lewis Research Center: Cleveland, Ohio. Accessed August 7, 2015.
[14] DeKock  R. L., Weltner Jr.  W., (1971), Spectroscopy of rare earth oxide molecules in inert matrices at 4.deg.K. Phys. Chem. 75: 514-519.
[15] Gabelnick S. D., Reedy  G. T., Chasanov  M. G., (1974), Infrared spectra and structure of some matrix isolated lanthanide and actinide oxides. Chem. Phys.  60: 1167-1172.
[16] Palard M., Balencie  J., Maguer  A., Hochepied J., (2010), Effect of hydrothermal ripening on the photoluminescence properties of pure and doped cerium oxide nanoparticles. Mater. Chem. Phys. 120: 79–88.
[17] NIST Standard Reference Database Number 69., (2016). NIST Chemistry Web Book. National Institute of Standards and Technology. United States of America.
[18] Vahur S., Teearu T., Peets P., Joosu L., Ivo Leito L., (2016), ATR-FT-IR spectral collection of conservation materials in the extended region of 80-4000 cm–1. Anal. Bioanal. Chem. 408: 3373–3379.
[19] Nakamoto, K., (2009), Infrared and raman spectra of inorganic and coordination compounds, Part A, Theory and Applications in Inorganic Chemistry, 6th Edition. John Wiley & Sons, Inc.
[20] Russell S., (1977), Physical methods in inorganic chemistry.  Urbarm Reillhold Publishil, g Coq., New York.
[21] Pascual J, Camassel J., Mathieu M., (1978), Fine structure in the intrinsic absorption edge of TiO2. Phys. Rev. B: Solid State. 18: 5606-5614.
[22] Martin W. C., Zalubas R., Hagan L., (1978), Atomic energy levels-the rare-earth elements, The Spectra of Lanthanum, Cerium, IBSNBS, Washington, D.C 20234.
[23] Epstein G. L., Reader J., (1982), Spectrum and energy levels of triply ionized Yttrium. J. Opt. Am., 72: 476-492.
[24] Zhao M., Han A., Ye M., Wu T., (2013), Preparation and characterization of Fe3+ doped Y2Ce2O7 pigments with high near-infrared reflectance. Solar Energy. 97: 350–355.
[25] Sadeghi S., MalekiIranian F., (2011), Solvent free oxidation of benzyl alcohol and its derivatives into corresponding aldehydes on nano structured ZnO as catalyst. J. Organic Chem. 3: 635-637.
[26] Potapenko E. V., Andreev P. Yu., (2010), Oxidation of benzyl alcohol and benzaldehyde with ozone in acetic acid. Russian J. Applied Chem. 83: 1243−1247.
[27] Higashimoto S., Kitao N., Yoshida N., Sakura T., Azuma m., Ohue H., Sakata Y., (2009), Selective photocatalytic oxidation of benzyl alcohol and its derivatives into corresponding aldehydes by molecular oxygen on titanium dioxide under visible light irradiation. J. Catalysis. 266: 279–285.
[28] Guo D., Wang Y., Zhao P., Bai M., Xin H., Guo Z., Li J., (2016), Selective aerobic oxidation of benzyl alcohol driven by visible light on gold nanoparticles supported on hydrotalcite modified by nickel Ion. Catalysts. 6: 64-69.
International Journal of Nano Dimension
Volume 8, Issue 4
October 2017
Pages 307-315

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