Microbiological induced corrosion of AA 6061 nuclear alloy in highly diluted media by Bacillus cereus RE 10

Microbiological studies of a spent nuclear fuel pool in Argentina were performed to evaluate the risk of microbiological induced corrosion and determine the cultivable bacterial population. Based on standard methods and sequencing of the 16sRNA gene, eighteen microorganisms were identified. Bacillus cereus RE 10 was the predominant organism isolated, and was selected to investigate the biofilm formation process and the corrosion effect on aluminum alloy AA 6061 and on pure aluminum (Al 99.999%). To simulate the environmental conditions, the experiments were performed using a highly diluted medium. After 20 days of exposure, major pits covered with deposits were found on AA 6061 samples exposed to B. cereus RE 10 but not on Al 99.999%. There was a close correlation between biofilm patches, corrosion deposits, pitting and Al-(Fe or Ti)-Si inclusions. We postulate that this correlation is a consequence of a light local alkalinization around the inclusions that produces changes in the expression pattern of B. cereus RE 10 and allows bacterial survival using other substrates. Under these conditions, the generated biofilm induces a crevice corrosion effect around the intermetallic inclusions of the alloy. Our results will be useful for further studies related to the microbial impact on nuclear safety in nuclear waste storage facilities in Argentina.