Paper No. 4
Presentation Time: 8:55 AM
Stability and Metastability in Zeolite Ion Exchange Reactions: The Case of Clinoptilolite and Heulandite
Ready ion exchange exhibited by many zeolites enjoys widespread application in a number of passive and engineered applications for the treatment and modification of aqueous solutions. Often, the range of exchangeable ion contents achievable experimentally exceeds that observed in nature. A salient example of this phenomenon is manifested by the isostructural zeolite species heulandite and clinoptilolite. Although both are readily exchanged over the whole compositional range between homoionic Na-, K-, and Ca-forms, in nature the more silica-rich species clinoptilolite exhibits a much wider range of exchangeable cation contents than does the more alumina-rich species heulandite. Natural heulandites are restricted to Ca-rich compositions, rarely exhibiting mole fractions of monovalent cations greater than 0.5, whereas clinoptilolites have mole fractions of monovalent cations that range from essentially 0 to 1. In order to elucidate the cause of this phenomenon, thermodynamic calculations of the stability of heulandite-clinoptilolite solid solutions were conducted. These calculations were based on the published solubility, calorimetric, and ion exchange experiments along with estimated thermodynamic properties of Si-Al exchange based on observations in other zeolite systems. The calculations indicate that Na-and K-rich heulandites are metastable with respect to aqueous solutions in equilibrium with albite-quartz and K-feldspar-quartz bearing assemblages, respectively. This indicates that experimentally-obtained monovalent cation rich heulandite compositions are themselves metastable and a consequence of the more ready kinetics of ion exchange relative to phase transformation. At elevated silica activities, Na- and K-rich clinoptilolite is stable relative to alkali feldspars and may persist as a metastable phase provided quartz saturation is not achieved. These results explain the discrepancy between experimentally-obtained compositions and observations of natural parageneses. Application of zeolite ion exchange for long-term applications such as radioactive waste repositories requires consideration of exchanged zeolite stability relative to phase assemblages buffered by diagenetic silicates containing ions involved in proposed exchange reactions.
© Copyright 2008 The Geological Society of America (GSA), all rights reserved. Permission is hereby granted to the author(s) of this abstract to reproduce and distribute it freely, for noncommercial purposes. Permission is hereby granted to any individual scientist to download a single copy of this electronic file and reproduce up to 20 paper copies for noncommercial purposes advancing science and education, including classroom use, providing all reproductions include the complete content shown here, including the author information. All other forms of reproduction and/or transmittal are prohibited without written permission from GSA Copyright Permissions.