K Pedersen1, M Motamedi, O Karnland, T Sandén. 1. Department of Cell and Molecular Biology, Microbiology Section, Göteborg University, Göteborg and Clay Technology AB, Ideon Research Centre, Lund, Sweden. pedersen@gmm.gu.se
Abstract
AIM: The fate of micro-organisms in the bentonite clay surrounding high-level radioactive waste (HLW)-containing copper canisters in a future Swedish underground (500 m) repository were investigated. METHODS AND RESULTS: Laboratory experiments were designed in which the mixing of various bacterial species with swelling bentonite was studied. A clear trend of fewer cultivable bacteria at depth was seen in the clay. This trend was consistent as the incubation time was increased from 8 h to 28 weeks. Sulphate-reducing bacteria were found to be active, reducing sulphate at the lowest density studied, 1.5 g cm-3, but sulphate reduction activity ceased at higher densities. CONCLUSIONS: The number of viable micro-organisms in an HLW repository bentonite clay buffer will decrease rapidly during swelling and very few viable cells will be present at full compaction. SIGNIFICANCE AND IMPACT OF THE STUDY: Sulphate-reducing bacteria will most probably not be able to induce corrosion of HLW-containing copper canisters.
AIM: The fate of micro-organisms in the bentonite clay surrounding high-level radioactive waste (HLW)-containing copper canisters in a future Swedish underground (500 m) repository were investigated. METHODS AND RESULTS: Laboratory experiments were designed in which the mixing of various bacterial species with swelling bentonite was studied. A clear trend of fewer cultivable bacteria at depth was seen in the clay. This trend was consistent as the incubation time was increased from 8 h to 28 weeks. Sulphate-reducing bacteria were found to be active, reducing sulphate at the lowest density studied, 1.5 g cm-3, but sulphate reduction activity ceased at higher densities. CONCLUSIONS: The number of viable micro-organisms in an HLW repository bentonite clay buffer will decrease rapidly during swelling and very few viable cells will be present at full compaction. SIGNIFICANCE AND IMPACT OF THE STUDY: Sulphate-reducing bacteria will most probably not be able to induce corrosion of HLW-containing copper canisters.