In situ synchrotron XRD investigation of the dehydration and high temperature carbonation of Ca(OH) sub(2)

The dehydration and high temperature carbonation reactions of Ca(OH) sub(2) are an essential part of a number of existing schemes aiming to apply the thermochemical CaO-CaCO sub(3) cycle ('Ca Looping') in emerging energy industries such as CO sub(2) capture, gasification and thermal energy...

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Bibliographic Details
Published in:CrystEngComm 2015-09, Vol.17 (38), p.7306-7315
Main Authors: Materic, V, Ingham, B, Holt, R
Format: Article
Language:English
Subjects:
Carbon dioxide
Carbonation
Dehydration
Diffraction patterns
Energy storage
Fittings
Gasification
Superheating
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Summary:The dehydration and high temperature carbonation reactions of Ca(OH) sub(2) are an essential part of a number of existing schemes aiming to apply the thermochemical CaO-CaCO sub(3) cycle ('Ca Looping') in emerging energy industries such as CO sub(2) capture, gasification and thermal energy storage. However, the underlying chemical mechanisms are poorly understood and the reaction kinetics exhibit a number of strange features such as the increased thermal stability of Ca(OH) sub(2), dubbed "superheating", observed in the presence of CO sub(2). In this work, in situ X-ray diffraction (XRD) measurements using a synchrotron source are coupled with full pattern fitting analysis to provide high-resolution and high-accuracy data on the evolution of Ca(OH) sub(2) crystalline structural parameters during the dehydration and carbonation reactions. This method has allowed new observations to be made that provide insight into the studied reaction mechanisms and disprove existing hypotheses as to the origin of superheating. A new hypothesis, involving the formation of an intermediate and permeable Ca(OH) sub(2) structure was formulated which can explain the growing body of observations in this area.
ISSN:1466-8033
DOI:10.1039/c5ce01379h