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Dehydration of the montmorillonite minerals

Published online by Cambridge University Press:  14 March 2018

R. Greene-Kelly
R. Greene-Kelly*
Affiliation:
Rothamsted Experimental Station, Harpenden, Hefts
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Extract

Studies of the effect of dehydration at temperatures greater than 150° on sorption by montmorillonites have shown that small interlayer cations such as lithium and magnesium promote an irreversible decrease in the amount of interlamellar sorption and a consequent marked fall in the cation exchange capacity as measured by conventional methods (1, 2, 3, 4). The other minerals of the group do not show this property (4), which is quite distinct from the supposed 'potassium fixation' reported in these minerals (5). This latter effect, which is small for montmorillonite, refers to the decreased rate of exchange of potassium as compared with smaller exchange cations especially after the potassium-saturated mineral has been dried at ]00° C., and has been shown to be much more marked in mica-like minerals with silicate layers of higher charge density (e.g. illites and vermiculites (6)). The amount of water sorbed by potassium-saturated montmorillonite is not significantly affected by drying at temperatures below 400° C. although it is less than that of most other montmorilIonites (3), due probably to the low hydration energy of the potassium ion (7).

Type
Research Article
Information
Mineralogical magazine and journal of the Mineralogical Society , Volume 30 , Issue 228 , March 1955 , pp. 604 - 615
Copyright
Copyright © 1955, The Mineralogical Society

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References

1. Hofmann, (U.) and Klemen, (R.), 1950. Verlust der Austauschfghigkeit yon Lithiumionen an Bentonit durch Erhitzung. Zeits. Anorg. Chem., vol. 262, pp. 9599.Google Scholar
2. Greene-Kelly, (R.), 1952. Irreversible dehydration in montmorillonite. Clay Minerals Bulletin, vol. l, pp. 221225.CrossRefGoogle Scholar
3. Gonzalez Garcia, (F.), 1950. Silicates del grupo de la montmorillonita. Anales de Edafología y Fisiología Vegetal, Madrid, vol. 9, p. 149.Google Scholar
4. Greene-Kelly, (R.), 1953.Irreversible dehydration in montmorillonite, Part II. Clay Minerals Bulletin, vol. 2, pp. 5256. Google Scholar
5. Raney, (W.A.) and Hoover, (C.D.), 1946. The release of artificially fixed potassium from kaolinite and montmorillonitic soils. Proe. Soil Sol. Soe. Amer., vol. ll , pp. 231237. Google Scholar
6. Barshad, (I.), 1948. Vermiculite and its relation to biotite as revealed by base exchange reactions, X-ray analysis, differential thermal curves, and water content. Amer. Min., vol. 33, pp. 655-678. [M.A. 10-462.]Google Scholar
7. Norrish, (K.), 1954. The swelling of montmorillonite. Discussion of Faraday Society on Flocculation (to be published).CrossRefGoogle Scholar
8. Greene-Kelly, (R.), 1953. The identification of montmorillonoids in clays. Journ. Soil Sci., vol. 4, pp. 233237. Google Scholar
9. Foster, (M.D.), 1951. The importance of exchangeable magnesium and cationexchange capacity in the study of montmorillonitic clays. Amer. Min., vol. 36, pp. 717730. [M.A. 11-455.]Google Scholar
10. Foster, (M.D.), 1953. Geochemical studies of clay minerals III. Geochim. Cosmochim. Acta, vol. 3, pp. 143154. Google Scholar
11. Earley, (J.W.), Osthaus, (B.B.), and Milne (I.It.), 1953. Purification and properties of montmorillonite. Amer. Min., vol.38, pp. 707–724. [M.A. 12-492.]Google Scholar
12. Brown, (G.) and Greene-Kelly, (R.), 1954. X-ray diffraction by a randomly interstratified clay mineral. Acta Cryst., vol. 7, pp. 101103. Google Scholar
13. Pask, (J.A.) and Davies, (B.), 1945. Thermal analysis of clay minerals and acid extraction of alumina from clays. U.S. Bureau of Mines, Tech. Paper no. 664, pp. 56-81.Google Scholar
14. Nagelschmidt, (G.), 1938. On the atomic arrangement and variability of the members of the montmorillonite group. Min. Mag., vol. 25, pp. 140155. Google Scholar
15. Ross, (C.S.) and Hendricks, (S.B.), 1945. Minerals of the montmorillonite group: their origin and relation to soils and clays. Prof. Paper U.S. Geol. Surv., no. 205-B.|[M.A. 10-26.]Google Scholar