Radioisotopic tracer technique for characterization of nuclear and non-nuclear grade ion exchange resins Tulsion A-23 and Indion-810

• Autorzy: Singare P. U.
• Języki publikacji: EN

Abstrakty

EN

In the present paper 82Br radioactive tracer isotopes was used for characterization of nuclear and non-nuclear grade ion exchange resins Tulsion A-23 and Indion-810 respectively. The bromide ion-isotopic exchange reactions were performed by equilibrating 1.000 g of conditioned resins in bromide form with labeled bromide ion solution of different concentrations ranging from 0.001 M to 0.004 M, in the temperature range of 30.0 °C to 45.0 °C. The resins were characterized by comparing the values of specific reaction rate (min-1), amount of bromide ion exchanged (mmol) and percentage of bromide ions exchanged under identical experimental conditions. It was observed that the above values decrease with rise in temperature and increases with increase in concentration of labeled bromide ion solution. From the experimental values of specific reaction rate, amount and percentage of bromide ions exchanged, it was observed that Tulsion A-23 resins are superior to Indion-810 resins under identical experimental conditions.

Słowa kluczowe

EN

anion exchange resins; radiotracer isotopes; Tulsion A-23; Indion-810; characterization

• Wydawca: Przedsiębiorstwo Wydawnictw Naukowych "DARWIN"
• Czasopismo: International Letters of Chemistry, Physics and Astronomy
• Rocznik: 2013
• Tom: Vol. 6
• Strony: 1--5
• Opis fizyczny: Bibliogr. 18 poz., tab., wykr.

Twórcy

autor

Singare P. U.

• Department of Chemistry, Bhavan's College, Munshi Nagar, Andheri (West), Mumbai 400058, India,

Bibliografia

• [1] Matsuda M., Funabashi K., Yusa H., J. Nuclear Science and Technology 24 (1987) 124.
• [2] Matsuda M., Funabashi K., Kawamura F., Uchida S., Ohsumi K., Nucl. Technol. 78 (1987) 62.
• [3] Xuejun L., Yiming X., Kangle L., Gencheng Z., J. Photochemistry and Photobiology 173 (2005) 121.
• [4] Buscher C., Donohoe R., Mecklenburg S., Berg J., Tait C., Huchton K., Morris D., Applied Spectroscopy 53 (1999) 943.
• [5] Van Loon L., Hummel W., Nuclear Technology 128 (1999) 388.
• [6] Tulupov P., Polyanskii N., Russian Chemical Reviews 42 (1999) 107.
• [7] McConnell Jr. J., Johnson D., Sanders Sr. R., Waste Management 13 (1993) 65.
• [8] Zahorodna M., Bogoczek R., Oliveros E., Braun A., Catalysis Today 129 (2007) 200.
• [9] Bolma A., Icemenerg A., Bucharest D., Power Tech. 1 (2005) 1.
• [10] Iwai Y., Yamanishi T., Hiroki A., Tamada M., Fusion Science and Technology 56 (2009) 163.
• [11] Gonder Z., Kaya Y., Vergili I., Barlas H., Aachen Membrane Colloquium 189 (2006) 303.
• [12] Chambree D., Cornelia I., Segal E., Cesro A., J. Thermal Analysis and Calorimetry 82 (2005) 3.
• [13] Ichikawa T., Hagiwara Z., J. Nuclear Science and Technology 10 (2004) 746.
• [14] Simister C., Caron F., Gedye R., J. Radioanalytical and Nuclear Chemistry 261 (2004) 523.
• [15] Sood D., Proc. Int. Conf. on Applications of Radioisotopes and Radiation in Industrial Development, B.A.R.C., Mumbai 1998, p 35.
• [16] Lokhande R., Singare P., Tiwari S., Russ. J. Physical Chemistry 83 (2009) 1389.
• [17] Lokhande R., Singare P., Kolte A., Radiochim. Acta 95 (2007) 595.
• [18] Lokhande R., Singare P., Dole M., J. Nuclear and Radiochemical Sciences 7 (2006) 29.