Preparation, characterization and photocatalytic performances of materials based on CS2-modified titanate nanotubes

An, H.; Hu, X.; Zhu, B.; Song, J.; Zhao, W.; Zhang, S.; Huan, W.

Artykuł - szczegóły

Tytuł artykułu

Preparation, characterization and photocatalytic performances of materials based on CS2-modified titanate nanotubes

Autorzy

An H. , Hu X. , Zhu B. , Song J. , Zhao W. , Zhang S. , Huan W.

Wybrane pełne teksty z tego czasopisma

Identyfikatory

Warianty tytułu

Języki publikacji

Abstrakty

CS2-modified titanate nanotubes (CS2/TiO2–NTs) are fabricated by reaction of CS2 and Ti–O2Na+ species on titanate nanotubes. Pb2+ ions are coated on the modified nanotubes by ion exchange (Pb/CS2/TiO2–NTs). The products are characterized by means of nitrogen adsorption-desorption isotherms at 77 K (BET method), transmission electron microscopy (TEM), X-ray photoelectron spectrometry (XPS), X-ray diffraction (XRD), atomic absorption spectrometry (AAS), and diffuse reflectance spectroscopy (DRS). The photocatalytic performances of the products are evaluated by monitoring their catalytic activities for degradation of methyl orange under UV light irradiation. The effects of calcination temperature and atmosphere on the photocatalytic performance are investigated. The results reveal that the photocatalytic activities of CS2/TiO2–NTs and Pb/CS2/TiO2–NTs are far higher than that of primary nanotubes, and the optimum calcination temperature is 500 °C under N2 atmosphere. It is also discovered that physically adsorbed Pb2+ ions affect the photocatalytic activity of Pb/CS2/TiO2–NTs obviously. The photocatalytic activity of washed Pb/CS2/TiO2–NTs is higher than that of the unwashed one under the same thermal treatment and reaction conditions.

Słowa kluczowe

titanate nanotubes CS2 xanthate Pb2+ ions photocatalytic performance

Wydawca

De Gruyter

Czasopismo

Materials Science Poland

Rocznik

2013

Tom

Vol. 31, No. 4

Strony

531--542

Opis fizyczny

Bibliogr. 69 poz., rys., wykr., tab.

Twórcy

autor

An H.

School of Environmental and Chemical Engineering, Tianjin Polytechnic University, Tianjin 300387, China Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

autor

Hu X.

Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

autor

Zhu B.

Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

autor

Song J.

Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

autor

Zhao W.

Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

autor

Zhang S.

Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

autor

Huan W.

hwp914@nankai.edu.cn

Tianjin Key Lab of Metal and Molecule-based Material Chemistry and Department of Chemistry, Nankai University, Tianjin 300071, China

Bibliografia

[1] DAKROURY G., LABIB SH., ABOU-NOUR F.H.,Mater Sci-Poland, 30 (2012), DOI: 10.2478/s13536-012-0022-3.
[2] HOFFMANN M. R., MARTIN S. T., CHOI W., BAHNEMANN D. W., Chem Rev, 95 (1995), 69.
[3] FUJISHIMA A., RAO T. N., TRYK D. A., J Photochem Photobiol C, 1 (2000), 1.
[4] CHU S. Z., INOUE S., WADA K., LI D., HANEDA H., AWATSU S., J Phys Chem B , 107 (2003), 6586.
[5] BAVYKIN D. V., FRIEDRICH J. M., WALSH F. C., Adv Mater, 18 (2006), 2807.
[6] TACHIKAWA T., FUJITSUKA M., MAJIMA T., J Phys Chem C, 111 (2007), 5259.
[7] IBHADON A. O., GREENWAY G. M., YUE Y., FALARAS P., TSOUKLERIS D., Appl Catal B-Environ ,84 (2008), 351.
[8] TAN A. W., PINGGUAN-MURPHY B., AHMAD R., AKBAR S. A., Ceram Int , 38 (2012), 4421.
[9] CHEN X., MAO S. S., Chem Rev, 107 (2007), 2891.
[10] BAVYKIN D. V., CRESSEY B. A., LIGHT M. E., WALSH F. C., Nanotechnology, 19 (2008), 275604.
[11] CHEN Q., PENG L. M., Int J Nanotechnol , 4 (2007), 44.
[12] YANG J. J., JIN Z. S., WANG X. D., LI W., ZHANG J. W., ZHANG S. L., GUO X. Y., ZHANG Z. J., Dalton T , 20 (2003), 3898.
[13] IDAKIEV V., YUAN Z. Y., TABAKOVA T., SU B. L.,Appl Catal A-Gen , 281 (2005), 149.
[14] MOR G. K., SHANKAR K., PAULOSE M., VARGHESE O. K., GRIMES C. A., Nano Lett, 6 (2006), 215.
[15] ZHU B. L., GUO Q., HUANG X. L., WANG S. R., ZHANG S. M., WU S. H., HUANG W. P., J Mol Catal A , 249 (2006), 211.
[16] AN H. Q., ZHU B. L.. LI J. X., ZHOU J., WANG S. R., ZHANG S. M., WU S. H., HUANG W. P., J Phys Chem C, 112 (2008), 18772.
[17] LINSEBIGLER A. L., LU G. Q., YATES J. T., Chem Rev, 95 (1995), 735.
[18] DIEBOLD U., Surf Sci Rep , 48 (2003), 53.
[19] DENG L. X., WANG S. R., LIU D. Y., ZHU B. L., HUANG W. P., WU S. H., ZHANG S. M., Catal Lett , 129 (2009), 513.
[20] LI D. Z., HUANG H. J., CHEN X., CHEN Z. X., LI W. J., YE D., FU X. Z., J Solid State Chem , 180 (2007), 2630.
[21] COLMENARES J. C., ARAMEND´IA M. A., MARINAS A., MARINAS J. M., URBANO F. J., Appl Catal A-Gen , 306 (2006), 120.
[22] ILIEV V., TOMOVA D., BILYARSKA L., ELIYAS A., PETROV L., Appl Catal B-Environ, 63 (2006), 266.
[23] WANG Y. Q., CHENG H. M., ZHANG L., HAO Y. Z., MA J. M., XU B., LI W. H., J Mol Catal A , 151 (2000), 205.
[24] YU Y., WU H. H., ZHU B. L., WANG S. R., HUANG W. P., WU S. H., ZHANG S. M., Catal Lett , 121 (2008), 165.
[25] CARVALHO HUDSON W. P., BATISTA ANA P. L., PETER H., RAMALHO TEODORICO C. P., J Hazard Mater, 184 (2010), 273.
[26] LI H., ZHU B. L., FENG Y. F., WANG S. R., ZHANG S. M., HUANG W. P., J Solid State Chem, 180 (2007), 2136.
[27] ZHU B. L., LI K. R., ZHOU J., WANG S. R., ZHANG S. M., WU S. H., HUANG W. P., Catal Commun, 9 (2008), 2323.
[28] WANG H., LEWIS J. P., J Phys-Condens Mat , 18 (2006), 421.
[29] NOSAKA Y., MATSUSHITA M., NISHINO J., NOSAKA A. Y., Sci Tech Adv Mater, 6 (2005), 143.
[30] SHAO G. S., ZHANG X. J., YU Z .Y., Appl Catal B-Environ, 82 (2008), 208.
[31] ASAHI R., MORIKAWA T., OHWAKI T., AOKI K., TAGA Y., Science, 293 (2001), 269.
[32] IM J. H., YANG S. J., YUN C. H., PARK C.R., Nanotechnology, 23 (2012), 035604.
[33] CARPIO E., ZUNIGA P., PONCE S., SOLIS J., RODRIGUEZ J., ESTRADA W., J Mol Catal A , 228 (2005),293.
[34] KHAN S. U. M., AL-SHAHRY M., INGLER JR W. B.,Science , 297 (2002), 2243.
[35] UMEBAYASHI T., YAMAKI T., TANAKA S., ASAI K.,Chem Lett, 32 (2003), 330.
[36] OHNO T., AKIYOSHI M., UMEBAYASHI T., ASAI K.,MITSUI T., MATSUMURA M., Appl Catal A-Gen, 265 (2004), 115.
[37] TIAN F. H., LIU C. B., J Phys Chem B, 110 (2006), 17866.
[38] YU H .F., J Phys Chem Solids, 68 (2007), 600.
[39] HONG X. T., WANG Z. P., CAI W. M., LU F., ZHANG J., YANG Y. Z., MA N., LIU Y., J Chem Mater, 17 (2005), 1548.
[40] YANG G., JIANG Z., SHI H., JONES M. O., XIAO T., EDWARDSB P. P., YANA Z., App Catal B-Environ, 96 (2010), 458.
[41] HAMAL D. B., KLABUNDE K. J., J Colloid Interf Sci, 311 (2007), 514.
[42] LI D., OHASHI N., HISHITA S., KOLODIAZHNYI T., HANEDA H., Solid State Chem , 178 (2005), 3293.
[43] LI D., HANEDA H., HISHITA S., OHASHI N., Chem Mater, 17 (2005), 2596.
[44] LUO H., TAKATA T., LEE Y., ZHAO J., DOMEN K., YAN Y., Chem Mater, 16 (2004), 846.
[45] CHAKRABORTY S., TARE V., Bioresource Technol , 97 (2006), 2407.
[46] AN H. Q., ZHU B. L., WU H. Y., ZHANG M., WANG S. R., ZHANG S. M., WU S. H., HUANG W. P., Chem J Chinese U, 29 (2008), 439.
[47] ZHAO X., JIA Q., SONG N., ZHOU W., LI Y., J Chem Eng Data, 55 (2010), 4428.
[48] VOGEL R., HOYER P., WELLER H., J Phys Chem-US , 98 (1994), 3183.
[49] PATIL R., LOKHANDE C., MANE R., GUJAR T., HAN S., J Non-Cryst Solids, 353 (2007), 1645.
[50] HONG J., CHOI D., KANG M., KIM D., KIM K., J Photoch Photobio A, 143 (2001), 87.
[51] CHEN S., PAULOSE M., RUAN C., MOR G., VARGHESE O., KOUZOUDIS D., GRIMES C., J Photoch Photobio A, 177 (2006), 177.
[52] ZHUKOVSKIY M. A., STROYUK A. L., SHVALAGIN V.V., SMIRNOVA N. P., LYTVYN O. S., EREMENKO A.M., J Photoch Photobio A , 203 (2009), 137.
[53] KASUGA T., HIRAMATSU M., HOSON A., SEKINO T.,NIIHARA K., Langmuir , 14 (1998), 3160.
[54] SUN H. Q., BAI Y., CHENG Y. P., JIN W. Q., XU N.P., Ind Eng Chem Res, 45 (2006), 4971.
[55] ZHOU M. H., YU J. G., J Hazard Mater ,152 (2008),1229.
[56] SHAO G. S., LIU L., MA T. Y., WANG F. Y., REN T.Z., YUAN Z. Y., Chem Eng J, 160 (2010), 370.
[57] LI Y. Z., HWANG D. S., LEE N. H., KIM S. J., ChemPhys Lett, 404 (2005), 25.
[58] DU X. Y., WANG Y., MU Y. Y., GUI L. L., WANG P.,TANG Y. Q., Chem Mater, 14 (2002), 3953.
[59] TACHIKAWA T., TOJO S., KAWAI K., ENDO M., FUJITSUKA M., OHNO T., NISHIJIMA K., MIYAMOTO Z., MAJIMA T., J Phys Chem B , 108 (2004), 19299.
[60] YANG X. X., CAO C. D., ERICKSON L., HOHN K., MAGHIRANG R., KLABUNDE K., Appl Catal B Environ, 91 (2009), 657.
[61] ZHANG S. M., CHEN Y. Y., YU Y., WU H. H., WANG S. R., ZHU B. L., HUANG W. P., WU S. H., J Nanopart Res, 10 (2008), 871.
[62] SAKTHIVEL S., KISCH H., Angew Chem Int Edit , 42 (2003), 4908.
[63] PAPIRER E., LACROIX R., DONNET J. B., NANSE G., FIOUX P. CHLORINATION, Carbon, 33 (1995), 63.
[64] WANG Y., HUANG Y., HO W., ZHANG L., ZOU Z., LEE S., J Hazard Mater, 169 (2009), 77.
[65] LI H. X., ZHANG X. Y., HUO Y. N., ZHU J., Environ Sci Technol, 41 (2007), 4410.
[66] MA R., BANDO Y., SASAKI T., Chem Phys Lett, 380 (2003), 577.
[67] CHEN Q., ZHOU W. Z., DU G. H., PENG L. M., Adv Mater, 14 (2002), 1208.
[68] ZHANG M., JIN Z. S., ZHANG J. W., GUO X. Y., YANG J. J., LI W., WANG X. D., ZHANG Z. J., J Mol Catal A , 217 (2004), 203.
[69] ZHANG Z., WANG C. C., ZAKARIA R., YING J. Y., J Phys Chem B, 102 (1998), 10871.

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Bibliografia

Identyfikator YADDA

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