- journal_title:Mineralogical Magazine
- Contributor:B. T. Swift ; P. B. Bamforth ; G. M. N. Baston
- Publisher:Mineralogical Society of Great Britain and Ireland
- Date:2012-12-01
- Format:text/html
- Language:en
- Identifier:10.1180/minmag.2012.076.8.22
- journal_abbrev:Mineralogical Magazine
- issn:0026-461X
- volume:76
- issue:8
- firstpage:3071
- section:Engineering barriers (near field)
In the UK, disposal of packaged intermediate-level radioactive waste may involve waste packages being placed in a geological disposal facility (GDF) and surrounded by a cementitious backfill. Cracking of the backfill could occur due to a number of mechanisms, and this could affect the post-closure performance of the GDF.
This work has assessed potential cracking in the backfill during the backfilling and early post-closure period of GDF vaults with an open crown space in a higher strength rock. From the comprehensive range of processes considered, three were identified as potentially causing cracking: (1) during backfilling, plastic settlement under solid horizontal surfaces could result in horizontal gaps beneath waste packages; (2) within days of backfilling, early-age thermal contraction of the backfill could result in primarily vertical cracks; (3) over a number of years, expansion of waste packages could result in large horizontal cracks.
A groundwater flow model incorporating a representation of the cracks was used to calculate flows through a backfilled GDF vault, and through the cracks themselves. Including cracks increased the flow rate significantly. A reactive transport model was used to estimate the evolution of the pore water chemistry as groundwater flows through the cracked backfill. Calcite and brucite were predicted to precipitate, with brucite subsequently dissolving. Calcite build-up could seal some cracks.