Qualification of montmorillonite purification process for nanoclay production

Authors

Abstract

Regarding the growing uses of the nanoclay for different applications nanoclay characterization has become highly important. However, there is not enough information about a developed characterization methodology of nanoclay materials. In this study the montmorillonite was purified using different physical or chemical methods and the purity of montmorillonite in the nanoclay samples were characterized using different methods such as XRD, SEM/EDX, FTIR, TG/DTA, and CEC. Results indicated that parallel comparison of results of different characterization methods would provide important information about the type of clay mineral, type of non-clay mineral in the samples, semi-quantification of minerals in produced nanoclay, and change in the nanometric characteristics of the nanoclay. Combination of XRD and SEM/EDX results provided interesting information about the amount of impurities in the nanoclay samples in addition to their structural morphology. Comparison of the CEC with the XRD results of the treated nanoclay samples provided information about type of clay in the nanoclay samples. And finally combination of XRD and TG results provided information about the type of other clay minerals (non-montmorillonite ones) in addition to existence of organic impurities in the nanoclay samples.

Keywords

References

[1] Shirzad-Sibonia M., Khataeec A., Hassanid A., Karaca S., “Preparation, characterization and application of a CTAB-modified nanoclay for the adsorption of an herbicide from aqueous solutions: Kinetic and equilibrium studies”, Comptes Rendus Chimie 18(2) (2015) 204-214.

[2] Nguemtchouin M. G. M., Ngassoum M. B., Kamga R., Deabate S., Lagerge S., Gastaldi E., Chalier P., Cretin M., “Characterization of inorganic and organic clay modified materials: An approach for adsorption of an insecticidal terpenic compound”, Applied Clay Science, 104 (2015) 110-118.

[3] Brigatti M.F., Galán E., Theng B.K.G., Chapter 2, “Structure and Mineralogy of Clay Minerals”, in Developments in Clay Science, B. Faïza and L. Gerhard, Editors. 2013, Elsevier. 21-81.

[4] Bergaya F., Lagaly G., Chapter 1 – “General Introduction: Clays, Clay Minerals, and Clay Science, in Developments in Clay Science”, B. Faïza and L. Gerhard, Editors. 2013, Elsevier. 1-19.

[5] Xi Y., Ding Z., He H., Frost R. L., “Structure of organoclays - an X-ray diffraction and thermogravimetric analysis study”. Journal of Colloid and Interface Science, 277 (2004) 116-120

[6] Brindley G.W., “Quantitative X-ray mineral analysis of clays. Crystal Structures of Clay Minerals and Their X-ray Identification”, 1980 411-438.

[7] Veiskarami M., Sarvi M.N., Mokhtari A.R., “Influence of the purity of montmorillonite on its surface modification with an alkyl-ammonium salt”, Applied Clay Science, 120 (2016) 111-120.

[8] Gharagozlou M., Naghibi S., “Preparation of vitamin B12–TiO2 nanohybrid studied by TEM, FTIR and optical analysis techniques”, Materials Science in Semiconductor Processing, 35 (2015) 166-173.

[9] Xue W., He H., Zhu J., Yuan P., “FTIR investigation of CTAB–Al–montmorillonite complexes”. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 67 (2007) 1030-1036.

[10] Zhou Q., Frost R. L., He H., Xi Y., “Changes in the surfaces of adsorbed para-nitrophenol on HDTMA organoclay—The XRD and TG study”. Journal of Colloid and Interface Science, 307 (2007) 50-55.

[11] Lv G., Chang P.-H., Xing X., Jiang W.-T., Jean J.-S., Li Z., “Investigation of intercalation of diphenhydramine into the interlayer of smectite by XRD, FTIR, TG-DTG analyses and molecular simulation”. Arabian Journal of Chemistry, in press.

[12] Thuc C.-N. H., Grillet A.-C., Reinert L., Ohashi F., Thuc H. H., Duclaux L., “Separation and purification of montmorillonite and polyethylene oxide modified montmorillonite from Vietnamese bentonites”. Applied Clay Science, 49 (2010) 229-238.

[13] Hillier S., D.G. Lumsdon, “Distinguishing opaline silica from cristobalite in bentonites: a practical procedure and perspective based on NaOH dissolution”. Clay Minerals, 43 (2008) 477-486.

[14] Gruner J.W., “Cristobalite in bentonite”. American Mineralogist, 25 (1940) 587-590.

[15] USGS, A Laboratory Manual for X-Ray Powder Diffraction. Washington, DC, US, Geological Survey, 2001.

[16] He H., Ma Y., Zhu J., Yuan P., Qing Y., “Organoclays prepared from montmorillonites with different cation exchange capacity and surfactant configuration”. Applied Clay Science, 48 (2010) 67-72.

[17] Meier L.P., Kahr G., “Determination of the cation exchange capacity (CEC) of clay minerals using the complexes of copper(II) ion with triethylenetetramine and tetraethylenepentamine”. Clays and Clay Minerals, 47 (1999) 386-388.

[18] Bergaya F., Lagaly G., Chapter 7.1, “Purification of Natural Clays”, Developments in Clay Science, B. Faïza and L. Gerhard, Editors. 2013, Elsevier 213-221.

[19] Earley, J.W., Osthaus B.B., Milne I.H., “Purification and Properties of Montmorillonite”. American Mineralogist, 38 (1953) 707-724.

[20] Aroke U.O., El-Nafaty U.A., “XRF, XRD and FTIR Properties and Characterization of HDTMA-Br Surface Modified Organo-Kaolinite Clay”. International Journal of Emerging Technology and Advanced Engineering, 4 (2014) 817-825.

[21] Alabarse F. G., Conceição R. V., Balzaretti N. M., Schenato F., Xavier A. M., “In-situ FTIR analyses of bentonite under high-pressure”. Applied Clay Science, 51 (2011) 202-208.
Iranian Journal of Crystallography and Mineralogy
Volume 25, Issue 3 - Serial Number 67
September 2017
Pages 557-566

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History

  • Receive Date: 02 July 2025
  • Revise Date: 04 February 2026
  • Accept Date: 02 July 2025

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