Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-29T07:48:58.287Z Has data issue: false hasContentIssue false
  • English
  • Français

A New Natural Analogue Study of the Interaction of Low-Alkali Cement Leachates and the Bentonite Buffer of a Radioactive Waste Repository

Published online by Cambridge University Press:  01 February 2011

W. Russell Alexander ,
Carlo A. Arcilla ,
Ian G. McKinley ,
Hideki Kawamura ,
Yoshiaki Takahashi ,
Kaz Aoki  and
Satoru Miyoshi
W. Russell Alexander
Affiliation:
Bedrock Geosciences, Auenstein, Switzerland.
Carlo A. Arcilla
Affiliation:
National Institute of Geological Sciences, University of the Philippines, Quezon City, Philippines.
Ian G. McKinley
Affiliation:
McKinley Consulting, Dättwil, Switzerland.
Hideki Kawamura
Affiliation:
Obayashi, Tokyo, Japan.
Yoshiaki Takahashi
Affiliation:
NUMO, Tokyo, Japan.
Kaz Aoki
Affiliation:
RWMC, Tokyo, Japan.
Satoru Miyoshi
Affiliation:
Obayashi, Tokyo, Japan.
Get access

Abstract

Bentonite plays a significant barrier role in many radioactive waste repository designs, where it has been chosen due to its favourable properties such as plasticity, swelling capacity, colloid filtration, low hydraulic conductivity and its stability in relevant geological environments. However, bentonite is unstable at high pH meaning that it could lose its favourable properties if interacted with hyperalkaline leachates from concrete construction materials (e.g. tunnel liners, grouts, etc.), seals and plugs and/or cementitious wastes in a repository. This fact has forced several national programmes to assess alternative construction and sealing materials such as low alkali cements. Recently, it has been assumed that the lower pH (typically pH 10-11) leachates of such cements will degrade bentonite to a much lesser degree than ‘standard’ OPC-based cement leachates (generally with an initial pH>13).

To date, few laboratory or in situ URL (underground rock laboratory) data are available to support the use of low alkali cements in conjunction with bentonites, partly because of the very slow kinetics involved. Consequently, a new project has focussed on finding an appropriate natural analogue site to provide long-term supporting data which will avoid the kinetic constraints of laboratory and URL experiments. Early results have identified an initial, very promising site at Mangatarem in the Philippines, where a quarry excavating bentonite and zeolites is found in the sedimentary carapace of the Zambales ophiolite. In the immediate vicinity of the quarry, ophiolite-derived hyperalkaline groundwaters are present and further field work (including geophysics surveys and borehole drilling) are now being planned to assess regional bentonite/hyperalkaline groundwater interaction. This paper presents an overview of the current status of the project and assesses the relevance of the study to improving understanding of low-alkali cement leachate/bentonite interaction.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1107: Scientific Basis for Nuclear Waste Management XXXI , 2008 , 493
Copyright
Copyright © Materials Research Society 2008

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1 Alexander, W.R. and McKinley, I.G. (1999) The chemical basis of near-field containment in the Swiss high-level radioactive waste disposal concept. pp 4769 in Chemical containment of wastes in the geosphere (eds. Metcalfe, R. and Rochelle, C.A.), Geol.Soc.Spec.Publ. No. 157, Geol Soc, London, UK. Google Scholar
2 Nagra, (2002) Project Opalinus Clay - Safety Report. Nagra Technical Report NTB 02-05, Nagra, Wettingen, Switzerland.Google Scholar
3 Haworth, A., Sharland, S.M., Tasker, P.W. and Tweed, C.J. (1987) Evolution of the groundwater chemistry around a nuclear waste repository. Sci. Basis Nucl. Waste Manag., XI, 425434 Google Scholar
4 Alexander, W.R. and Neall, F.B. (2007) Assessment of potential perturbations to Posiva-s SF repository at Olkiluoto caused by construction and operation of the ONKALO facility. Posiva Working Report 2007-35, Posiva, Olkiluoto, Finland.Google Scholar
5 NUMO (2007) The NUMO structured approach to HLW disposal in Japan. NUMO Report TR-07-02, NUMO, Tokyo, Japan.Google Scholar
6 JAEA (2007) Second progress report on R&D for TRU waste disposal in Japan. JAEA Review 2007-010/FEPC TRU-TR2-2007-01, JAEA, Tokai, Japan.Google Scholar
7 Umeki, H. (2007) Holistic assessment to put mobile radionuclides in perspective. Proc. MOFAP-07, January 16-19 2007, La Baule, France. (in press).Google Scholar
8 R.Metcalfe and C.Walker (2004) Proceedings of the International Workshop on Bentonite-Cement Interaction in Repository Environments 14-16 April 2004, Tokyo, Japan. NUMO Tech. Rep. NUMO-TR-04-05, NUMO, Tokyo, Japan.Google Scholar
9 Alexander, W.R., Clark, I.D., Degnan, P., Elie, M., Kamei, G., Khoury, H., Mäder, U., Milodowski, A.E., Pedersen, K., Pitty, A.F., Salameh, E., Smellie, J.A.T., Techer, I. and Trotignon, L. (2007) Cementitious natural analogues: safety assessment implications of the unique systems in Jordan. Phys. Chem. Earth (submitted).Google Scholar
10 Gray, M.N. and Shenton, B.S. (1998) For better concrete, take out some of the cement. In Proceedings of the 6th ACI/CANMET symposium on the durability of concrete, Bangkok, Thailand, 31st May - 5th June, 1998. CANMET Technical Report, CANMET, Ottawa, Canada.Google Scholar
11 Miller, W.M., Alexander, W.R., Chapman, N.A., McKinley, I.G., and Smellie, J.A.T. (2000) Geological disposal of radioactive wastes and natural analogues. Waste management series, vol. 2, Pergamon, Amsterdam, The Netherlands.Google Scholar
12 www.natural-analogues.com (NAWG, the Natural Analogue Working Group, web site)Google Scholar
13 Alexander, W.R., Gautschi, A. and Zuidema, P. (1998) Thorough testing of performance assessment models: the necessary integration of in situ experiments, natural analogues and laboratory work. Sci. Basis Nucl. Waste Manag. XXI, 10131014 Google Scholar
14 Pitty, A.F. (ed), (2007) A natural analogue study of cement buffered, hyperalkaline groundwaters and their interaction with a repository host rock IV: an examination of the Khushaym Matruk (central Jordan) and Maqarin (northern Jordan) sites. ANDRA Technical Report, ANDRA, Paris, France (in press).Google Scholar
15 McKinley, I.G., Bath, A.H., Berner, U., Cave, M. and Neal, C. (1988) Results of the Oman analogue study. Radiochim Acta, 44/45, 311316 Google Scholar
16 Pate, S.M., McKinley, I.G. and Alexander, W.R. (1994) Use of natural analogue test cases to evaluate a new performance assessment TDB. CEC Report EUR15176EN, Brussels, Belgium.Google Scholar
17 Barnes, I. and ‘Neill, J.R.O (1969) The relationship between fluids in some fresh alpine-type ultramafics and possible modern serpentinisation, western United States. Geol. Soc. Amer. Bull., 80, 19471960 Google Scholar
18 Sader, J.A., Leybourne, M.I., McClenaghan, M.B. and Hamilton, S.M. (2007) Low-temperature serpentinisation processes and kimberlite groundwater signatures in the Kirkland Lake and Lake Timiskiming kimberlite fields, Ontario, Canada: implications for diamond exploration. Geochem., 7, 321 Google Scholar
19 Abrajano, T.A., Sturchio, N.C., Bohlke, J.K., Lyon, G.L., Poredar, R.J. and Stevens, C.M. (1988) Methane-hydrogen gas seeps, Zambales Ophiolite, Philippines: deep or shallow origin? Chem. Geol., 71, 211222 Google Scholar
20 Neal, C. and Stanger, G. (1983) Hydrogen generation from mantle source rocks in Oman. Earth Planet. Sci. Lett., 66, 315320.Google Scholar
21 Wright, K. and Catlow, C.R.A. (1996) Calculations on the energetics of water dissolution in wadsleyite. Phys. Chem. Mins 23, 3841 Google Scholar
22 Hosgörmez, H. (2007) Origin of the natural gas seep of çirali (Chimera), Turkey: Site of the first Olympic fire. J. Asian Earth Sci. 30, 131141 Google Scholar
23 http://www.philzeolite.com/htms/saileDeposit.htm#body (the web site of the Saile bentonite/zeolite producing company)Google Scholar
24 West, J.M., Coombs, P., Gardner, S.J. and Rochelle, C.A. (1995) The microbiology of the Maqarin site, Jordan. A natural analogue for cementitious radioactive waste repositories. Sci. Basis Nucl. Waste Manag. XVIII, pp 181189.Google Scholar
25 McKinley, I.G., Alexander, W.R., Arcilla, C.A., Kawamura, H. and Takahashi, Y. (2007) IPHAP: a new natural analogue of bentonite alteration by cement leachates. Proc ISRSM conference, Daejeon, ROK. KHMP report, Daejeon, ROK.Google Scholar
26 Kawata, T., Umeki, H. and McKinley, I.G. (2006) Knowledge Management: The Emperor-s New Clothes? Proc. 11th International High-Level Radioactive Waste Management Conference 2006, Las Vegas, Nevada, April 30-May 4, pp.12361243 Google Scholar
27 Neal, C. and Shand, P. (2002) Spring and surface water quality of the Cyprus Ophiolites. Hydrol. Earth System Sci., 6, 797817 Google Scholar
28 Vuorinen, U., Lehikoinen, J., Imoto, H., Yamamoto, T. and Cruz, M. Alonso (2005) Injection Grout for Deep Repositories, Subproject 1: Low-pH cementitious Grout for Larger Fractures, Leach Testing of Grout Mixes and Evaluation of the Long-Term Safety. Posiva Working Report 2004-46, Posiva, Olkiluoto, Finland.Google Scholar
29 Karnland, O., Sellin, P. and Olsson, S. (2006) Mineralogy and some physical properties of the San José bentonite - a natural analogue to buffer material exposed to saline groundwater. Mat. Res. Soc. Symp. Proc, 807, 16 Google Scholar