Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-08T01:23:57.871Z Has data issue: false hasContentIssue false

Estimation of the Zeolite Contents of Tuffaceous Samples from the Bigadiç Clinoptilolite Deposit, Western Turkey

Published online by Cambridge University Press:  28 February 2024

Ahmet Sirkecioğlu
Affiliation:
Department of Chemical Engineering, Istanbul Technical University, 80626 Maslak, Istanbul, Turkey
Ayşe Erdem-Şenatalar
Affiliation:
Department of Chemical Engineering, Istanbul Technical University, 80626 Maslak, Istanbul, Turkey
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Variation of the NH4+-exchange and CO2-adsorption capacities with zeolite content was investigated in detail to assess the potential use of these capacities for the estimation of the zeolite contents of the samples taken from the Bigadiç clinoptilolite deposit in western Anatolia, as an alternative to the widely used semi-quantitative X-ray diffraction (XRD) technique. Samples with known clinoptilolite contents taken from 2 different zones with fine- and coarse-grained tuffs of the Bigadiç deposit were used for this purpose. Na-enriched forms of the samples were prepared by repeated ion-exchange with NaCl solutions, and NH4+-forms by repeated Na exchange followed by NH4+ exchange with NH4Cl solutions, which in turn were calcined to obtain the H-forms. NH4+-exchange capacities by Kjeldahl analyses of the NH4+-forms and CO2 adsorption isotherms in the 0 to 100 kPa range of Na- and H-forms of the samples were determined. Dubinin-Astakhov model parameters were calculated from the isotherm data.

A strong relationship exists between the experimental CO2-adsorption capacities at 100 kPa of the Na-forms and the zeolite contents of the samples. Although the Dubinin-Astakhov model represented the isotherm data quite well, the relationships between the amounts of adsorbate at saturation pressure, calculated from the model, and the zeolite contents of the samples were weaker. The strength of the relationship between NH4+ exchange capacities and zeolite contents was seen to vary with the zone of origin. There is a very strong relationship between the adsorption and ion-exchange capacities of the samples in their Na-forms taken from the fine-grained zone, indicating that either ion-exchange or adsorption capacity measurements can be used to estimate the zeolite contents of the samples taken from this zone, whereas, significant diffusion hindrance was observed against ion-exchange of hydrated cations from aqueous solutions for some samples from the coarse-grained zone. Inspection of the data pointed to systematic errors in the zeolite contents determined by a semi-quantitative XRD technique. When both zones are considered together, CO2-adsorption capacities at 100 kPa of the samples in their Na-forms can be used as a reliable measure of the zeolite content, which in turn is an important index to predict the performance of natural samples in various applications.

Type
Research Article
Copyright
Copyright © 1996, The Clay Minerals Society

References

Ackley, M.W. and Yang, R.T.. 1992. Adsorption characteristics of high-exchange clinoptilolites. Ind Eng Chem Res 30: 25232530.CrossRefGoogle Scholar
Ames, L.L.. 1960. The cation sieve properties of clinoptilolite. Am Mineral 45: 689700.Google Scholar
Ataman, G.. 1977. Zeolite occurrences in western Anatolia. Earth Sci 3: 8594 (in Turkish).Google Scholar
Barrer, R.M. and Murphy, E.V.T.. 1970. Influence of decationation and dealumination on sorption by mordenite and clinoptilolite. J Chem Soc (A): p 25062514.CrossRefGoogle Scholar
Baysal, O., Gündoğdu, N., Temel, A. and Öner, F.. 1986. Geological investigation of the zeolite formations in Bigadiç. Hacettepe University Project Report: YUVAM. p 85-2 (In Turkish).Google Scholar
Daniel, C.. 1976. Applications of statistics to industrial experimentation. New York: John Wiley & Sons. 296 p.CrossRefGoogle Scholar
Dubinin, M.M.. 1975. Physical adsorption of gases and vapors in micropores. In: Cadenhead, D.A., editor. Progress in surface and membrane science. New York: Academic Press. p 170.Google Scholar
Erdem-Şenatalar, A., Sirkecioğlu, A., Güray, I., Esenli, F. and Kumbasar, I.. 1993. Characterization of the clinoptilolite-rich tuffs of Bigadiç: Variation of the ion-exchange capacity with pretreatments and zeolite content. In: von Balmoos, R., Higgins, J.B., Treacy, M.M.J., editors. Proceedings of Ninth International Zeolite Conference. Boston: Butterworth-Heinemann. Volume 2. p 223230.CrossRefGoogle Scholar
Etibank. 1989. Investigation of the technological properties of Bigadiç zeolites. Etibank Project Report. 112 p (in Turkish).Google Scholar
Flanigen, E.M. and Mumpton, F.A.. 1981. Commercial properties of natural zeolites. In: Mumpton, F.A., editor. Mineralogy and geology of natural zeolites. Washington D.C.: Mineralogical Society of America. p 165174.Google Scholar
Johnson, M.F.L.. 1978. Estimation of the zeolite content of a catalyst from nitrogen adsorption. J Catalysis 52: 425431.CrossRefGoogle Scholar
Kallo, D., Papp, J. and Valyon, J.. 1982. Adsorption and catalytic properties of sedimentary clinoptilolite and mordenite from Tokaj Hills, Hungary. Zeolites 2: 1316.CrossRefGoogle Scholar
Lieu, K., Williford, C.W. and Reynolds, W.R.. 1988a. Cation exchange characteristics of Gulf Coast clinoptilolite. In: Kallo, D., Sherry, H.S., editors. Occurrence, properties and utilization of natural zeolites. Budapest: Akademiai Kiado. p 449461.Google Scholar
Lieu, K., Williford, C.W. and Reynolds, W.R.. 1988b. Comparison of wet chemistry CEC determinations. In: Kallo, D., Sherry, H.S., editors. Occurrence, properties and utilization of natural zeolites. Budapest: Akademiai Kiado. p 541550.Google Scholar
Ming, D.W. and Dixon, J.B.. 1987. Quantitative determination of clinoptilolite in soils by a cation-exchange capacity method. Clays Clay Miner 35: 463468.CrossRefGoogle Scholar
Mumpton, F.A.. 1988. Development of uses for natural zeolites: A critical commentary. In: Kallo, D., Sherry, H.S., editors. Occurrence, properties and utilization of natural zeolites. Budapest: Akademiai Kiado. p 333366.Google Scholar
Sersale, R.. 1985. Natural zeolites: Processing, present and possible applications. In: Drzaj, B., Hocevar, S., Pejovnik, S., editors. Zeolites. Amsterdam: Elsevier. p 503512.Google Scholar
Sheppard, R.A. and Gude, A.J.. 1982. Mineralogy, chemistry, gas adsorption and NH4+-exchange capacity for selected zeolitic tuffs from western United States. U.S. Geological Survey Open-File Report: 82-969. 16 p.CrossRefGoogle Scholar
Sirkecioğlu, A., Esenli, F., Kumbasar, I., Eren, R.H. and Erdem-Şenatalar, A.. 1990. Mineralogical and chemical properties of Bigadiç clinoptilolite. In: Savaşçin, M.Y., Eronat, A.H., editors. Proc International Earth Science Congress on Aegean Regions. IESCA Pub. No. 2, 1: 291301.Google Scholar
Sirkecioğlu, A., Altav, Y. and Erdem-Şenatalar, A.. 1995. Adsorption of H2S and SO2 on Bigadiç clinoptilolite. Separation Science and Technology 30: 27472762.CrossRefGoogle Scholar
Triebe, R.W., Tezel, H., Erdem-Şenatalar, A. and Sirkecioğlu, A.. Promising air purifications on clinoptilolite. In: Karge, H.G., Weitkamp, J., editors. Zeolite science 1994: Recent progress and discussions. Amsterdam: Elsevier. p. 219220.Google Scholar
Valyon, J., Papp, J. and Kallo, D.. 1981. Estimation of mordenite and clinoptilolite content in Hungarian rhyolitic tuffs. In: Sersale, R., Collella, C., Aiello, R., editors. Recent Progress Reports and Discussion of the 5th. International Convention on Zeolites. Napoli: Giannini. p 199202.Google Scholar
Worrall, W.E.. 1986. Clays and ceramic raw materials. London: Elsevier. 239 p.Google Scholar
Yücel, H. and Culfaz, A.. 1988. Characterization of clinoptilolites of western Anatolia. In: Kallo, D., Sherry, H.S., editors. Occurrence, properties and utilization of natural zeolites. Budapest: Akademiai Kiado. p 99108.Google Scholar