International Journal of Chemical Synthesis and Chemical Reactions

Open Access  Subscription or Fee Access

Zirconium (IV) telluroiodate has been synthesized as a new inorganic cation exchanger by adding a mixture of aqueous solution of 0.1 M potassium iodate and 0.1 M sodium tellurite to aqueous solution of 0.1 M zirconium (IV) oxychloride under varying mixing ratios at pH 1. Its ion exchange capacity for Na+ was found to be 1.85 meqg1 of dry exchanger. The material has been characterized on the basis of chemical composition, FTIR, TGA, SEM and XRD. The chemical stability and thermal stability of the exchange material have also been studied. Further, various ion exchange studies such as pH titration, determination of ion exchange capacities for various metal ions and distribution behavior have been performed on this material. Keywords: cation exchanger, characterization, heteropolyacidic salt, synthesis, zirconium (IV) telluroiodate

Clearfield A. Ed. Inorganic Ion Exchange Materials. Boca Raton FL: CR Press, Inc.; 1982.

Costantino U., Vivani R. New developments in ion exchange, In: Proceeding International Conference Ion Exchange. ICIE'91Tokyo. 1991, 205p.

Ferragina C., Massucci M.A., Tomlison A.A.G.J. Chem Soc Dalton Trans. 1990, 1191.

Cross J.E., Hooper E.W. Ion Exchange for Industry. Streat M. (Ed.) Conf. Proceeding, Cambridge, Ellis Hardwood; 1988.

Hafez M.A.H., Kenway I.M.M., Akl

M.A., et al. Talanta. 2001; 53: 749p.

Khan A.A., lam M.M. React Funct Polym. 2003; 55: 277p.

Khan A.A., Alam M.M. Anal Chim Acta. 2004; 504: 253p.

Ferragina C., Cafarelli P., Stefanis A., et al. Mater Res Bull. 2001; 36: 1799p.

Hayshi H., Onoda Y., Iwasaki T. Nippon Ion Kokan Gakkaishi. 2002; 11: 32p.

Clearfield A., Wang Z. J Chem Soc Dalton Trans. 2002; 7: 2937p.

Varshney K.G., Jain V., Tayal N. Indian J Chem Tech. 2003; 10: 186p.

Ajagekar S.D., Turel Z.R., J Ind Counc Chem. 2000; 17: 29p.

Quereshi S.Z., Jamhour R.M.A.Q., Rahman N. Ann Chim (Paris). 1996; 21: 609p.

Kenta O., Abe M. Solvent Extr Ion Exch. 1996; 14: 1137p.

Quereshi S.Z., Asif G., Khayer M.R. Ann Chim (Paris). 1999; 24: 545p.

Niwas R., Khan A.A. Chem Environ Res. 1998; 7: 289p.

Suzuki T.M., Bomani J, Matsunaga H., et al. React Funct Polym. 2000; 43: 165p.

Dyer A., Shaheen M., Tahira Z., et al. J Mater Chem. 1997; 7: 1875p.

Varshney K.G., Pandith A.H., Gupta U. Langmuir. 1998; 14: 7353p.

Nabi S.A., Usmani S., Rahman N. Ann Chim Fr. 1996; 21: 521p.

Gupta A.P., Verma G.L., Ikram S. React Funct Polym. 2000; 43: 33p.

Gupta A.P., Varsheney P.K. React Funct Polym. 1997; 32: 67p.

Singh P., Rawat J.P., Rahman N. Indian J Chem. 2002; 8: 1616p.

[24] Singh P., Rawat J.P., Rahman N. Talanta. 2003, 59443p.

Topp N.E., Pepper K.W. J Chem Soc. 1949; 3290p.

Reilley C.N., Schmid R.W., Sadek F.S. J Chem Edu. 1957; 35: 355p.

Snell F.D., Snell C.T. Colorimetric Methods of Analysis. Vol. 2, Princeton, New Jersey: D. Van Nostrand; 1949, 335p.

Furman N.H. Standard Methods of Chemical Analysis. 6th Edn., Vol. 1, Princeton, New Jersey: D. Van Nostrand; 1963, 934p.

Snell F.D., Snell C.T. Colorimetric Methods of Analysis. Vol. 2, Princeton, New Jersey: D. Van Nostrand; 1949, 741p.

Vogel A.I. Text Book of Quantitative Inorganic Analysis. 4th Edn., London: Longman; 1978, 173p.

Nabi S.A., Islam A., Rahman N. Adsorp Sci Technol. 1999; 17: 629p.

Qureshi S.Z., Rahman N. Bull Soc Chim (France). 1987; 6: 959p.

Rahman M.K., Haq A.M.S. J Chromatograph. 1979; 53: 613p.

Alberti G., Torocca E., Conte A. J Inorg Nucl Chem. 1966; 28: 607p.

Verma K.K., Gupta D., Sanghai S.K., et al. Talanta. 1988; 35: 917p.