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Accelerated Weathering of Composite Cements Used for Immobilisation

Published online by Cambridge University Press:  01 February 2011

Paulo H. R. Borges ,
Neil B. Milestone  and
Roger E. Streatfield
Paulo H. R. Borges
Affiliation:
Immobilisation Science Laboratory, Engineering Materials, University of Sheffield, Mappin St, Sheffield S13JD, UK
Neil B. Milestone
Affiliation:
Immobilisation Science Laboratory, Engineering Materials, University of Sheffield, Mappin St, Sheffield S13JD, UK
Roger E. Streatfield
Affiliation:
Magnox Electric Ltd., BNG, Berkeley Centre, Berkeley, Gloucestershire GL13 9PB
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Abstract

Trying to estimate the long-term durability of cemented wasteforms is a difficult task as the cement matrix is a reactive medium and interactions can occur with the encapsulated waste as well as with the environment. There are few studies of samples that have been stored under controlled conditions for more than 10-15 years. Wasteforms are now being expected to last hundreds of years, much of that likely to be in some form of storage where sample integrity is important. There is also the concern that results from any long-term samples may only be indicative as both formulations and materials change with time.

This paper discusses changes in physical properties that occur in composite cements when some of the short-term accelerated procedures employed in construction testing are applied to encapsulating matrices. Changes after increased temperature of curing, wetting/drying and accelerated carbonation are discussed.

Many of the encapsulating formulations currently used are composite cements where large replacement levels of OPC with supplementary cementing materials (SCMs) such as PFA or BFS are made, primarily to reduce heat output. Accelerating the exposure conditions, either by increasing temperature or through wetting/drying has the effect of changing the hydration pattern of the composite cement by generating more hydration in the SCMs than would normally occur. The large amount of porosity that occurs because of limited hydration allows intrusion of gases and ready movement of water, so the samples subjected to accelerated testing do not appear as durable as expected if stored at ambient.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1107: Scientific Basis for Nuclear Waste Management XXXI , 2008 , 305
Copyright
Copyright © Materials Research Society 2008

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References

[1] Hill, J. and Sharp, J. H., “The mineralogy and microstructure of three composite cements with high replacement levels,” Cem. Conrc. Comp., 24, 191199, 2002.Google Scholar
[2] Utton, C. A., “The encapsulation of a BaCO3 waste in composite cements,” PhD thesis Department of Engineering Materials, The University of Sheffield, 2006, pp. 249.Google Scholar
[3] Gorce, J.P. and Milestone, N. B., “Probing the microstructure and water phases in composite cement blends,” Cem. Con. Res., 37, 310317, 2007.Google Scholar
[4] Glasser, F. P., “Cement conditioning of nuclear waste – where do we go?” presented at DoE Workshop, Savannah River, December 2006.Google Scholar
[5] Borges, P. H. R., Milestone, N. B., and Lynsdale, C. J., “Volume changes, cracking and durability of cement grouts subjected to accelerated wetting and drying cycles,”, International RILEM Conference on Volume Changes of Hardening Concrete: Testing and Mitigation, Lyngby, Denmark, 2006, 241–250 Google Scholar