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The Dehydration of Tobermorite

Published online by Cambridge University Press:  01 January 2024

H. F. W. Taylor
H. F. W. Taylor*
Affiliation:
Department of Chemistry, University of Aberdeen, Scotland
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Abstract

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Tobermorite [Ca4 (Si6O18H2)Ca·4H2O] is a hydrated calcium silicate mineral with a layer structure which in some respects resembles that of vermiculite. Its dehydration has been studied using single crystals from Ballycraigy, N. Ireland. The three most frequently encountered hydration states are characterized by basal spacings (d002) of 14.0, 11.3 and 9.35Å. Dehydration to the 9.35Å state is complete by 300°C and is accompanied by a stacking change so that the pseudo-cell (a 5.58, b 3.66, c 18.70Å) becomes A-face centered. The 9.35Å structure persists up to 700°C, by which temperature all the water has been expelled, and there is some evidence that interlayer Si-O-Si bonds are formed to an increasing extent as the temperature rises.

At about 800°C, the 9.35Å hydrate changes to β-CaSiO3 twinned in two orientations. The b-axis of the 9.35Å hydrate becomes b for both orientations of the product, and the (201) planes of the latter are formed parallel to the (101̄) and (101) planes of the original material. The mechanism of the change is discussed and is compared with some other transformations occurring under similar conditions. An orientation-determining step is suggested in which the principal effect is a migration of silicon atoms or ions, the calcium—oxygen skeleton remaining relatively undisturbed.

Type
Article
Information
Clays and Clay Minerals (National Conference on Clays and Clay Minerals) , Volume 6 , February 1957 , pp. 101 - 109
Copyright
Copyright © Clay Minerals Society 1957

References

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