Synthesis of Low TENORM Zirconium Sulfate from ZrO(OH)2 with Sulfuric Acid

https://doi.org/10.22146/ijc.60298

Rahmatika Alfia Amliliana(1*), Muzakky Muzakky(2)

(1) Center for Accelerator Science and Technology (CAST), National Nuclear Energy Agency, Jl. Babarsari POB 6101 Yk bb, Yogyakarta 55281, Indonesia
(2) Center for Accelerator Science and Technology (CAST), National Nuclear Energy Agency, Jl. Babarsari POB 6101 Yk bb, Yogyakarta 55281, Indonesia
(*) Corresponding Author

Abstract


Zirconium sulfate (ZS) has become one of the alternative chemical compounds for substituting traditional tannery substances using chromium(III) which was not environmentally friendly. The purpose of this research was to synthesize ZS from ZrO(OH)2 using H2SO4 with low Technologically Naturally Occurring Radioactive Material (TENORM) content. This ZS synthesis process shortened the old processing flow at which plenty of chemical reactors were used. The results showed that with 300 mg of feed, 600 mL of 95% H2SO4, at a temperature of 250 °C, the contact time of 150 min, the obtained conversion was 77.76%. Furthermore, in this 95% acid leaching reactor, the SiO2 content was still 2.79% and it was not TENORM free yet, but the FTIR and XRD images were in accordance with BDH standards. Moreover, the quenching process results had been free of SiO2 and TENORM content, but they still contained 1.48% HfO2. The surface of the TEM images from the quenching results had been in the form of elongated and transparent crystals. The result of the economic feasibility analysis showed that the new ZS synthesis process was more economical or profitable when it was compared to the old ZS synthesis process, with a BCR value of 1.258.


Keywords


TENORM; acid leaching; quenching process; FTIR; XRD; XRF; TEM; BCR

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References

[1] Sah, N.K., 2013, Greener Approach to Leather Techniques, Thesis, Centria University of Applied Sciences, Finland.

[2] Crudu, M., Deselnicu, V., Mutlu, M.M., Gulumser, G., Bitlisli, B.O., Basaran, B., and Zengin, A.C.A., 2010, New tanning agents based on titanium and zirconium, Int. Conf. Adv. Mater. Syst., 1, 27–32.

[3] Castiello, D., Calvanese, G., Puccin, M., Salvadori, M., Seggiani, M., and Vitolo, S., 2011, A technical feasibility study on titanium tanning to obtain upper quality versatile leather, XXXI IULTCS Congress, 1–9.

[4] BAPETEN, 2009, Intervensi terhadap paparan yang berasal dari technologically enhanced naturally occurring radioactive material, Peraturan Kepala Badan Pengawas Tenaga Nuklir Nomor 9 Tahun 2009, Jakarta.

[5] Liu, R., Xue, T., Song, J., Wang, Y., Qi, T., Qu, J., and Du, A., 2014, Removal of silicon in acid leaching and flocculation processes during zirconium oxychloride octahydrate production, Ceram. Int., 40 (6), 8801–8808.

[6] Liu, J., Song, J., Qi, T., Zhang, C., and Qu, J., 2016, Controlling the formation of Na2ZrSiO5 in alkali fusion process for zirconium oxychloride production, Adv. Powder Technol., 27 (1), 1–8.

[7] Perks, C., and Mudd, G., 2019, Titanium, zirconium resources and production: A state of the art literature review, Ore Geol. Rev., 107, 629–646.

[8] Beyer, G.H., Koerner, E.L., and Olson, E.H., 1955, Conversion of zirconium sulfates to anhydrous zirconium tetrafluoride, Ames Laboratory ISC Technical Reports, 102, U.S. Department of Energy, Iowa, USA.

[9] Levenspiel, O., 1999, Chemical Reaction Engineering, 3rd Ed., John Wiley & Sons, Inc., New York.

[10] Houchin, M.R., and Sinha, H.N., 1987, Process for the production of zirconium sulphate, Eur. Patent EP0289537A1.

[11] Miao, Z., Zhou, J., Zhao, J., Liu, D., Bi, X., Chou, L., and Zhuo, S., 2017, A novel mesoporous sulfated zirconium solid acid catalyst for Friedel-Crafts benzylation reaction, Appl. Surf. Sci., 411, 419–430.

[12] Heshmatpour, F., and Aghakhanpour, R.B., 2012, Synthesis and characterization of superfine pure tetragonal nanocrystalline sulfated zirconia powder by a non-alkoxide sol-gel route, Adv. Powder Technol., 23 (1), 80–87.

[13] Rabee, A.I.M., Mekhemer, G.A.H., Osatiashtiani, A., Isaacs, M.A., Lee, A.F., Wilson, K., and Zaki, M.I., 2017, Acidity-reactivity relationships in catalytic esterification over ammonium sulfate-derived sulfated zirconia, Catalysts, 7 (7), 204.

[14] Shi, G., Yu, F., Yan, X., and Li, R., 2017, Synthesis of tetragonal sulfated zirconia via a novel route for biodiesel production, J. Fuel Chem. Technol., 45 (3), 311–316.

[15] Ma, L., Lv, E., Du, L., Han, Y., Lu, J., and Ding, J., 2017, A flow-through tubular catalytic membrane reactor using zirconium sulfate tetrahydrate-impregnated carbon membranes for acidified oil esterification, J. Energy Inst., 90 (6), 875–883.

[16] Hauli, L., Wijaya, K., and Armunanto, R., 2018, Preparation and characterization of sulfated zirconia from a commercial zirconia nanopowder, Orient. J. Chem., 34 (3), 1559–1564.

[17] Rachmat, A., Trisunaryanti, W., Sutarno, and Wijaya, K., 2017, Synthesis and characterization of sulfated zirconia mesopore and its application on lauric acid esterification, Mater. Renewable Sustainable Energy, 6 (3), 13.

[18] Mftah, A., Alhassan, F.H., Al-Qubaisi, M.S., El Zowalaty, M.E., Webster, T.J., Sh-eldin, M., Rasedee, A., Taufiq-Yap, Y.H., and Rashid, S.S., 2015, Physicochemical properties, cytotoxity, and antimicrobial activity of sulphated zirconia nanoparticles, Int. J. Nanomed., 10 (1), 765–774.

[19] Mossayebi, Z., Saririchi, T., Rowshanzamir, S., and Parnian, M.J., 2016, Investigation and optimization of physicochemical properties of sulfated zirconia/sulfonated poly (ether ether ketone) nanocomposite membranes for medium temperature proton exchange membrane fuel cells, Int. J. Hydrogen Energy, 41 (28), 12293–12306.

[20] Ibrahim, A.A., Salama, R.S., El-Hakam, S.A., Khder, A.S., and Ahmed, A.I., 2021, Synthesis of sulfated zirconium supported MCM-41 composite with high rate adsorption of methylene blue and excellent heterogeneous catalyst, Colloids Surf., A, 616, 126361.

[21] Imelda, Marsudi, and Yoga, 2019, Analisis biaya pengolahan pasir zirkon (ZrSiO4) menjadi pasir zirkon berkadar ZrO2 ≥ 65,5% di PT. Sinar Hasil Alam, JeLAST, 6 (1), 1–6.

[22] Sasmitaloka, K., Jusnita, N., and Andayani, A., 2015, Analisis kelayakan finansial pendirian industri vanilin dengan bahan baku vanili basah (Vanilli spp), JSEP, 8 (3), 1–8.

[23] Frej, E.A., Ekel, P., and de Almeida, A.T., 2021, A benefit-to-cost ratio based approach for portfolio selection under multiple criteria with incomplete preference information, Inf. Sci., 545, 487–498.



DOI: https://doi.org/10.22146/ijc.60298

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