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Abstract

Abrstract

The present study is part of a wider investigation to develop an alternative cementing system for the encapsulation of problematic low and intermediate level radioactive waste. It has been suggested that alternative cementing systems, with lower internal pH than conventional Portland cement based composite cements, may reduce the corrosion of some reactive metals and may be beneficial for the long term durability of wasteforms. A potential alternative is an acid–base cementing system, based on mixing calcium aluminate cement (CAC) with acidic phosphate solutions. Although these systems have been studied previously, there has been no systematic investigation to identify phosphates for producing suitable matrixes for application in radioactive waste encapsulation. In the current study, monophosphate modified CAC formulations did not set or develop significant strength, whereas polyphosphate modified CAC formulations exhibited rapid setting and strength development. It is proposed that polyphosphate modified systems form amorphous reaction products, which act as binders between the partially and unreacted CAC particles, and were responsible for high strength development. Thermogravimetric analysis and scanning electron microscopy results suggest that this binding matrix consists of amorphous calcium phosphate and alumina gel. The results presented in this investigation suggest that polyphosphate modified CAC has potential as an alternative cementing system for radioactive waste encapsulation.

Keywords

Calcium aluminate cement Calcium phosphate cement Encapsulation Immobilisation Aluminium Corrosion

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References

Glasser

: ‘Progress in the immobilization of radioactive wastes in cement’, Cem. Concr. Res., 1992, 22, 201–216.

Glasser

: ‘Fundamental aspects of cement solidification and stabilisation’, J. Hazard. Mater., 1997, 52, (2–3), 151–170.

Atkins

, Glasser

: ‘Application of Portland cement-based materials to radioactive waste immobilization’, Waste Manage., 1992, 12, (2–3), 105–131.

Setiadi

, Milestone

, Hill

, Hayes

: ‘Corrosion of aluminium and magnesium in BFS composite cements’, Adv. Appl. Ceram., 2006, 105, 191–196.

The 2010 UK Radioactive Waste Inventory–Main Report, Department of Energy and Climate and Nuclear Decommissioning Authority, Cumbria, UK, URN 10D/985 NDA/ST/STY(11)0004, ISBN 978-1-905985-21-0, February 2011 (access via http://www.nda.gov.uk/ukinventory).

Milestone

: ‘Reactions in cement encapsulated nuclear wastes: need for toolbox of different cement types’, Adv. Appl. Ceram., 2006, 105, (1), 13–20.

‘Proposed research and development strategy’, Nuclear Decommissioning Authority Radioactive Waste Management Directorate, 2008, Access via http://www.nda.gov.uk/loader.cfm?csModule = security/getfile&pageid = 20962.

Wilson

, Nicholson

: ‘Theory of acid–base cements’, in ‘Acid–base cements: their biomedical and industrial applications’, 5–29; 1993, Cambridge, Press Syndicate of the University of Cambridge.

Wagh

: ‘Introduction to chemically bonded ceramics’, in ‘Chemically bonded phosphate ceramics: 21st century materials with diverse applications’, 1–13; 2004, Oxford, Elsevier Ltd.

10.

Sugama

, Taylor

: ‘Interfacial and mechanical behavior of fiber-reinforced calcium phosphate cement composites’, Cem. Concr. Compos., 1994, 16, (2), 93–106.

11.

Sugama

: ‘Hot Alkali carbonation of sodium metaphosphate modified fly ash/calcium aluminate blend hydrothermal cements’, Cem. Concr. Res., 1996, 26, (11), 1661–1672.

12.

Sugama

, Allan

, Hill

: ‘Calcium phosphate cements prepared by acid–base reaction’, J. Am. Ceram. Soc., 1992, 75, (8), 2076–2087.

13.

Sugama

, Carciello

: ‘Strength development in phosphate-bonded calcium aluminate cements’, J. Am. Ceram. Soc., 1991, 74, (5), 1023–1030.

14.

Sugama

, Weber

, Brothers

: ‘Sodium-polyphosphate-modified fly ash/calcium aluminate blend cement: durability in wet, harsh geothermal environments’, Mater. Lett., 2000, 44, (1), 45–53.

15.

Sugama

, Carciello

: ‘Carbonation of hydrothermally treated phosphate-bonded calcium aluminate cements’, Cem. Concr. Res., 1992, 22, (5), 783–792.

16.

Sugama

, Carciello

: ‘Carbonation of calcium phosphate cements after long-term exposure to Na₂CO₃-laden water at 250°C’, Cem. Concr. Res., 1993, 23, (6), 1409–1417.

17.

Sugama

, Carciello

: ‘Sodium phosphate-derived calcium phosphate cements’, Cem. Concr. Res., 1995, 25, (1), 91–101.

18.

Sugama

, Weber

, Brothers

: ‘Resistance of sodium polyphosphate-modified fly ash/calcium aluminate blend cements to hot H₂SO₄ solution’, Cem. Concr. Res., 1999, 29, (12), 1969–1976.

19.

Sugama

, Wetzel

: ‘Microsphere-filled lightweight calcium phosphate cements’, J. Mater. Sci., 1994, 29, (19), 5165–5176.

20.

, Brown

: ‘Mechanical behavior and microstructural development in phosphate modified high alumina cement’, Cem. Concr. Res., 1992, 22, (6), 1192–1200.

21.

, Brown

: ‘Hydration of sodium phosphate-modified high alumina cement’, J. Mater. Res., 1994, 9, (5).

22.

Walter

, Odler

: ‘Investigation of MgO and CaO/Al₂O₃ polyphosphate cements’, Adv. Cem. Res., 1996, 8, (29), 41–46.

23.

Collier

: National Nuclear Laboratory, Personal communication, 2010.

24.

Hayes

: National Nuclear Laboratory, Personal communication, 2010.

25.

‘Methods of testing cement’, ‘Determination of setting times and soundness’, BS EN 196-3:2005+A1:2008, 2005.

26.

Bushnell-Watson

, Sharp

: ‘The application of thermal analysis to the hydration and conversion reactions of calcium aluminate cements’, Materiales de Construccion, 1992, 42, (228), 13–32.

27.

Bensted

: ‘Calcium aluminate cements’, in ‘Structure and performance of cements’, (ed. , Bensted

, ed et al.); 2002, London, Spon Press.

28.

Bradbury

, Callaway

, Double

: ‘The conversion of high alumina cement/concrete’, Mater. Sci. Eng., 1976, 23, (1), 43–53.

29.

Scrivener

, Campas

: ‘Calcium aluminate cements’, in ‘Lea's chemistry of cement and concrete’, (ed. P. C. Hewlett), 4th edn, 711–782; 2006, Oxford, Butterworth-Heinemann.

30.

Dorozhkin

: ‘Amorphous calcium (ortho)phosphates’, Acta Biomater., 2010, 6, (12), 4457–4475.

31.

Dorozhkin

: ‘Calcium orthophosphates in nature, biology and medicine’, Materials, 2009, 2, (2), 399–498.

32.

Shannon

: ‘Revised effective ionic radii and systematic studies of interatomic distances in halides and chalcogenides’, Acta Crystallogr. A, 1976, 32A, (5), 751–767.

Phosphate modified calcium aluminate cement for radioactive waste encapsulation

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