[1. Zegeye, A., et al., Bacterial and iron oxide aggregates mediate secondary iron mineral formation: green rust versus magnetite. Geobiology2010,8 (3), 209-222.10.1111/j.1472-4669.2010.00238.x]Search in Google Scholar
[2. Diósi, G., et al., Corrosion influenced by biofilms during wet nuclear waste storage. International Biodeterioration & Biodegradation2003,51 (2), 151-156.10.1016/S0964-8305(02)00138-5]Search in Google Scholar
[3. Li, F.-s., et al., Corrosion inhibition of stainless steel by a sulfate-reducing bacteria biofilm in seawater. International Journal of Minerals, Metallurgy, and Materials2012,19 (8), 717-725.10.1007/s12613-012-0618-y]Search in Google Scholar
[4. Sheng, X., et al., The influence of sulphate-reducing bacteria biofilm on the corrosion of stainless steel AISI 316. Corrosion Science2007,49 (5), 2159-2176.10.1016/j.corsci.2006.10.040]Search in Google Scholar
[5. Yuan, S. J., et al., The Influence of the Marine Aerobic Pseudomonas Strain on the Corrosion of 70/30 Cu-Ni Alloy. ECS Transactions2007,2 (9), 159-192.10.1149/1.2408937]Search in Google Scholar
[6. Mankowski, J.; Szklarska-Smialowska, Z., Studies on accumulation of chloride ions in pits growing during anodic polarization Corrosion Science1975,15, 493-501.]Search in Google Scholar
[7. Suzuki, T., et al., Composition of Anolyte Within Pit Anode of Austenitic Stainless Steels in Chloride Solution. Corrosion1973,29, 18-22.10.5006/0010-9312-29.1.18]Search in Google Scholar
[8. Belkaid, S., et al., Effect of biofilm on naval steel corrosion in natural seawater. Journal of Solid State Electrochemistry2010,15 (3), 525-537.10.1007/s10008-010-1118-5]Search in Google Scholar
[9. Hernández-Gayosso, M. J., et al., Microbial consortium influence upon steel corrosion rate, using the electrochemical impedance spectroscopy technique. Materials and Corrosion2004,55 (9), 676-683.10.1002/maco.200303791]Search in Google Scholar
[10. Chen, S., et al., Corrosion behavior of copper under biofilm of sulfate-reducing bacteria. Corrosion Science2014,87, 407-415.10.1016/j.corsci.2014.07.001]Search in Google Scholar
[11. Dong, Z. H., et al., Heterogeneous corrosion of mild steel under SRB-biofilm characterised by electrochemical mapping technique. Corrosion Science2011,53 (9), 2978-2987.10.1016/j.corsci.2011.05.041]Search in Google Scholar
[12. Xu, P., et al., Chemical and electron microbial influenced corrosion. Journal of Chemical and Pharmaceutical Research2013,5 (12), 476-481.]Search in Google Scholar
[13. Bergel, A., Recent Advances in Electron Transfer Between Biofilms and Metals. Advanced Materials Research2007,20/21, 329-334.10.4028/www.scientific.net/AMR.20-21.329]Search in Google Scholar
[14. Dinh, H. T., et al., Iron corrosion by novel anaerobic microorganisms. Nature2004,427, 829-832.10.1038/nature0232114985759]Search in Google Scholar
[15. Pérez, E. J., et al., Influence of Desulfovibrio sp. biofilm on SAE 1018 carbon steel corrosion in synthetic marine medium. Corrosion Science2007,49 (9), 3580-3597.10.1016/j.corsci.2007.03.034]Search in Google Scholar
[16. Babauta, J. T.; Beyenal, H., Mass transfer studies of Geobacter sulfurreducens biofilms on rotating disk electrodes. Biotechnol Bioeng2014,111 (2), 285-94.10.1002/bit.25105424783323996084]Search in Google Scholar
[17. Deslouis, C.; Tribollet, B., Recent developments in the electro-hydrodynamic (EHD) impedance technique. Journal of Electroanalytical Chemistry2004,572 (2), 389-398.10.1016/j.jelechem.2004.03.035]Search in Google Scholar
[18. L’Hostis, E., et al., Characterization of Biofilms Formed on Gold in Natural Seawater by Oxygen Diffusion Analysis. Corrosion1997,53 (10), 4-10.10.5006/1.3280433]Search in Google Scholar
[19. Pires, L., et al., Online monitoring of biofilm growth and activity using a combined multi-channel impedimetric and amperometric sensor. Biosens Bioelectron2013,47, 157-63.10.1016/j.bios.2013.03.01523570679]Search in Google Scholar
[20. Liu, H., et al., Specification of sulfate reducing bacteria biofilms accumulation effects on corrosion initiation. Materials and Corrosion2007,58 (1), 44-48.10.1002/maco.200603984]Search in Google Scholar
[21. King, F., et al., Modelling long term corrosion behaviour of copper canisters in KBS-3 repository. Corrosion Engineering, Science and Technology2011,46 (2), 217-222.10.1179/18211Y.0000000004]Search in Google Scholar
[22. Schutz, M. K., et al., Combined geochemical and electrochemical methodology to quantify corrosion of carbon steel by bacterial activity. Bioelectrochemistry2014,97, 61-8.10.1016/j.bioelechem.2013.07.00324064199]Search in Google Scholar
[23. Zhang, H., et al., Study of biofilm influenced corrosion on cast iron pipes in reclaimed water. Applied Surface Science2015,357, 236-247.10.1016/j.apsusc.2015.09.021]Search in Google Scholar
[24. Behrends, T., et al., Implementation of microbial processes in the performance assessment of spent nuclear fuel repositories. Applied Geochemistry2012,27 (2), 453-462.10.1016/j.apgeochem.2011.09.014]Search in Google Scholar
[25. Féron, D.; Crusset, D., Microbial induced corrosion in French concept of nuclear waste underground disposal. Corrosion Engineering, Science and Technology2014,49 (6), 540-547.10.1179/1743278214Y.0000000193]Search in Google Scholar
[26. King, F., Microbiologically Influenced Corrosion of Nuclear Waste Containers. Corrosion2009,65 (4), 233-251.10.5006/1.3319131]Search in Google Scholar
[27. King, F., Container Materials for the Storage and Disposal of Nuclear Waste. Corrosion2013,69 (10), 986-1011.10.5006/0894]Search in Google Scholar
[28. Supplemental Environmental Impact Statement for a Geologic Repository for the Disposal of Spent Nuclear Fuel and High-Level Radioactive Waste at Yucca Mountain, Nye County, Nevada; DOE/EIS-0250F-S1; 2008.]Search in Google Scholar
[29. Pedersen, K. Microbial features, events and processes in the Swedish final repository for lowand intermediate-level radioactive waste; SKB Technical Report R-01-05; 2001.]Search in Google Scholar
[30. Jolley, D. M., et al., Microbial Impacts to the Near-Field Environment Geochemistry: a model for estimating microbial communities in repository drifts at Yucca Mountain. Journal of Contaminant Hydrology2003,62-63, 553-575.10.1016/S0169-7722(02)00187-0]Search in Google Scholar
[31. Wang, Y.; Francis, A. J., Evaluation of Microbial Activity for Long-Term Performance Assessments of Deep Geologic Nuclear Waste Repositories Journal of Nuclear and Radiochemical Sciences2005,6 (1), 43-50.10.14494/jnrs2000.6.43]Search in Google Scholar
[32. Pedersen, K. Microbial processes in radioactive waste disposal; SKB Technical Report TR-00-04; 2000.]Search in Google Scholar
[33. Mulligan, C., et al., Some effects of microbial activity on the evolution of clay-based buffer properties in underground repositories. Applied Clay Science2009,42 (3-4), 331-335.10.1016/j.clay.2008.03.002]Search in Google Scholar
[34. Fukunaga, S., et al., Investigation of Microorganisms in Bentonite Deposits. Geomicrobiology Journal2005,22 (7-8), 361-370.10.1080/01490450500248788]Search in Google Scholar
[35. Bengtsson, A., et al. Microbial sulphide-producing activity in MX-80 bentonite at 1750 and 2000 kg m−3 wet density; SKB Technical Report R-15-05; 2015.]Search in Google Scholar
[36. Masurat, P., et al., Microbial sulphide production in compacted Wyoming bentonite MX-80 under in situ conditions relevant to a repository for high-level radioactive waste. Applied Clay Science2010,47 (1-2), 58-64.10.1016/j.clay.2009.01.004]Search in Google Scholar
[37. Stroes-Gascoyne, S., Microbial occurrence in bentonite-based buffer, backfill and sealing materials from large-scale experiments at AECL‘s Underground Research Laboratory. Applied Clay Science2010,47 (1-2), 36-42.10.1016/j.clay.2008.07.022]Search in Google Scholar
[38. Hajj, H. E., et al., Microbial corrosion of P235GH steel under geological conditions. Physics and Chemistry of the Earth, Parts A/B/C2010,35 (6-8), 248-253.10.1016/j.pce.2010.04.007]Search in Google Scholar
[39. Lovecký, M. Ukládací obalový soubor pro hlubinné úložiště. Výpočet stínění pro palivo Gd-2M.; Škoda JS Ae 15516; 2014.]Search in Google Scholar
[40. Brown, A. R., et al., The impact of gamma radiation on sediment microbial processes. Appl Environ Microbiol2015,81 (12), 4014-25.10.1128/AEM.00590-15]Search in Google Scholar
[41. Bruhn, D. F., et al., Microbial biofilm growth on irradiated, spent nuclear fuel cladding. Journal of Nuclear Materials2009,384 (2), 140-145.10.1016/j.jnucmat.2008.11.008]Search in Google Scholar
[42. Battista, J. R., et al., Why is Deinococcus radiodurans so resistant to ionizing radiation? Trends in Microbiology1999,7 (9), 362-365.10.1016/S0966-842X(99)01566-8]Search in Google Scholar
[43. Lopez-Fernandez, M., et al., Bacterial Diversity in Bentonites, Engineered Barrier for Deep Geological Disposal of Radioactive Wastes. Microbial Ecology2015,70 (4), 922-935.10.1007/s00248-015-0630-726024740]Search in Google Scholar
[44. Stroes-Gascoyne, S., et al., Microbial Community Analysis of Opalinus Clay Drill Core Samples from the Mont Terri Underground Research Laboratory, Switzerland. Geomicrobiology Journal2007,24 (1), 1-17.10.1080/01490450601134275]Search in Google Scholar
[45. Stroes-Gascoyne, S.; Gascoyne, M., The Introduction of Microbial Nutrients into A Nuclear Waste Disposal Vault during Excavation and Operation. Environmental Science and Technology1998,32 (3), 317-326.10.1021/es970496t]Search in Google Scholar
[46. Stoulil, J., et al., Influence of temperature on corrosion rate and porosity of corrosion products of carbon steel in anoxic bentonite environment. Journal of Nuclear Materials2013,443 (1-3), 20-25.10.1016/j.jnucmat.2013.06.031]Search in Google Scholar
[47. Hallbeck, L.; Pedersen, K., Culture-dependent comparison of microbial diversity in deep granitic groundwater from two sites considered for a Swedish final repository of spent nuclear fuel. FEMS Microbiol Ecol2012,81 (1), 66-77.10.1111/j.1574-6941.2011.01281.x22188407]Search in Google Scholar
[48. Yang, C., et al., Modelling geochemical and microbial consumption of dissolved oxygen after backfilling a high level radiactive waste repository. Journal of Contaminant Hydrology2007,93 (1-4), 130-148.10.1016/j.jconhyd.2007.01.00817328991]Search in Google Scholar
[49. Choung, S., et al., Biogeochemical changes at early stage after the closure of radioactive waste geological repository in South Korea. Annals of Nuclear Energy2014,71, 6-10.10.1016/j.anucene.2014.03.021]Search in Google Scholar
[50. King, F. A review of the properties of pyrite and the implications for corrosion of the copper canister; SKB Technical Report TR-13-19; 2013.]Search in Google Scholar
[51. Persson, J., et al. Microbial incidence on copper and titanium embedded in compacted bentonite clay; SKB Technical Report R-11-22; 2011.]Search in Google Scholar
[52. King, F. Stress corrosion cracking of copper canisters; SKB Technical Report TR-10-04; 2010.]Search in Google Scholar
[53. Turnbull, A. A Review of the Possible Effects of Hydrogen on Lifetime of Carbon Steel Nuclear Waste Canisters; Nagra Technical Report 09-04; 2009.]Search in Google Scholar
[54. Esnault, L., et al., Metallic corrosion processes reactivation sustained by iron-reducing bacteria: Implication on long-term stability of protective layers. Physics and Chemistry of the Earth, Parts A/B/C2011,36 (17-18), 1624-1629.10.1016/j.pce.2011.10.018]Search in Google Scholar
[55. Libert, M., et al., Impact of microbial activity on the radioactive waste disposal: long term prediction of biocorrosion processes. Bioelectrochemistry2014,97, 162-8.10.1016/j.bioelechem.2013.10.00124177136]Search in Google Scholar
[56. Moreira, R., et al., Influence of hydrogen-oxidizing bacteria on the corrosion of low carbon steel: Local electrochemical investigations. Bioelectrochemistry2014,97, 69-75.10.1016/j.bioelechem.2013.10.00324177135]Search in Google Scholar
[57. Amend, J. P.; Shock, E. L., Energetics of overall metabolic reactions of thermophilic and hyperthermophilic Archaea and Bacteria. FEMS Microbiol. Rev.2001,25 (2), 175–243.]Search in Google Scholar
[58. Libert, M., et al., Molecular hydrogen: An abundant energy source for bacterial activity in nuclear waste repositories. Physics and Chemistry of the Earth, Parts A/B/C2011,36 (17-18), 1616-1623.10.1016/j.pce.2011.10.010]Search in Google Scholar
[59. Pitonzo, B. J., et al., Microbiologically Influenced Corrosion Capability of Bacteria Isolated from Yucca Mountain. Corrosion2004,60 (1), 64-74.10.5006/1.3299233]Search in Google Scholar
[60. Kosec, T., et al., Post examination of copper ER sensors exposed to bentonite. Journal of Nuclear Materials2015,459, 306-312.10.1016/j.jnucmat.2015.01.058]Search in Google Scholar
[61. Rosborg, B., et al., Corrosion rate of pure copper in an oxic bentonite/saline groundwater environment. Corrosion Engineering, Science and Technology2011,46 (2), 148-152.10.1179/1743278210Y.0000000015]Search in Google Scholar
[62. Bairi, L. R., et al., Microbially induced corrosion of D9 stainless steel–zirconium metal waste form alloy under simulated geological repository environment. Corrosion Science2012,61, 19-27.10.1016/j.corsci.2012.04.019]Search in Google Scholar
[63. Karimi, S.; Alfantazi, A. M., Electrochemical Corrosion Behavior of Orthopedic Biomaterials in Presence of Human Serum Albumin. Journal of the Electrochemical Society2013,160 (6), C206-C214.10.1149/2.052306jes]Search in Google Scholar
[64. Xu, Z., et al., Monitoring bacterial-demineralization of human dentine by electrochemical impedance spectroscopy. J Dent2010,38 (2), 138-48.10.1016/j.jdent.2009.09.013]Search in Google Scholar
[65. Beese-Vasbender, P. F., et al., Electrochemical characterization of direct electron uptake in electrical microbially influenced corrosion of iron by the lithoautotrophic SRB Desulfopila corrodens strain IS4. Electrochimica Acta2015,167, 321-329.10.1016/j.electacta.2015.03.184]Search in Google Scholar
[66. Castaneda, H.; Benetton, X. D., SRB-biofilm influence in active corrosion sites formed at the steel-electrolyte interface when exposed to artificial seawater conditions. Corrosion Science2008,50 (4), 1169-1183.10.1016/j.corsci.2007.11.032]Search in Google Scholar
[67. Kuş, E., et al., The effect of different exposure conditions on the biofilm/copper interface. Corrosion Science2007,49 (8), 3421-3427.10.1016/j.corsci.2007.03.019]Search in Google Scholar
[68. Webster, B. J., et al., Microbiologically Influenced Corrosion of Copper in Potable Water Systems—pH Effects. Corrosion2000,56 (9), 942-950.10.5006/1.3280598]Search in Google Scholar
[69. Liu, J., et al., The corrosion behavior of 70/30 copperzinc alloy under the biofilm of sulfate-reducing bacteria. Materials and Corrosion2001,52, 833-837.10.1002/1521-4176(200111)52:11<833::AID-MACO833>3.0.CO;2-9]Search in Google Scholar
[70. Chang, X., et al., Study of Fe3Al Corrosion Behavior in Simulating Marine Biofilm Environment. Materials and Manufacturing Processes2010,25 (5), 302-306.10.1080/10426911003747790]Search in Google Scholar
[71. Jayaraman, A., et al., Axenic aerobic biofilms inhibit corrosion of copper and aluminum. Applied Microbiology Biotechnology1999,52, 787±790.10.1007/s002530051592]Search in Google Scholar
[72. Zuo, R., et al., The importance of live biofilms in corrosion protection. Corrosion Science2005,47 (2), 279-287.10.1016/j.corsci.2004.09.006]Search in Google Scholar
[73. Patel, C., et al., Combined spectrophotometric electrochemical impedance imaging system for biofilm research. Journal of the Association for Laboratory Automation2005,10 (1), 16-23.10.1016/j.jala.2004.08.013]Search in Google Scholar
[74. Kim, T., et al., Influence of attached bacteria and biofilm on double-layer capacitance during biofilm monitoring by electrochemical impedance spectroscopy. Water Res2011,45 (15), 4615-22.10.1016/j.watres.2011.06.01021762943]Search in Google Scholar
[75. Sridharan, D., et al., Redox behavior of biofilm on glassy carbon electrode. Bioelectrochemistry2011,82 (2), 135-9.10.1016/j.bioelechem.2011.06.00621784716]Search in Google Scholar
[76. Estrada-Leypon, O., et al., Simultaneous monitoring of Staphylococcus aureus growth in a multi-parametric microfluidic platform using microscopy and impedance spectroscopy. Bioelectrochemistry2015,105, 56-64.10.1016/j.bioelechem.2015.05.00626004850]Search in Google Scholar
[77. Goncalves, J. J.; Govind, R., Rapid evaluation of biofilm attachment promoters and biofilm growth orientation using a mini-impedimetric device. Sensors and Actuators B: Chemical2009,143 (1), 341-348.10.1016/j.snb.2009.07.036]Search in Google Scholar
[78. Muñoz-Berbel, X., et al., On-chip impedance measurements to monitor biofilm formation in the drinking water distribution network. Sensors and Actuators B: Chemical2006,118 (1-2), 129-134.10.1016/j.snb.2006.04.070]Search in Google Scholar
[79. Paredes, J., et al., Comparison of real time impedance monitoring of bacterial biofilm cultures in different experimental setups mimicking real field environments. Sensors and Actuators B: Chemical2014,195, 667-676.10.1016/j.snb.2014.01.098]Search in Google Scholar
[80. Paredes, J., et al., Real time monitoring of the impedance characteristics of Staphylococcal bacterial biofilm cultures with a modified CDC reactor system. Biosens Bioelectron2012,38 (1), 226-32.10.1016/j.bios.2012.05.02722705402]Search in Google Scholar
[81. Paredes, J., et al., Interdigitated microelectrode biosensor for bacterial biofilm growth monitoring by impedance spectroscopy technique in 96-well microtiter plates. Sensors and Actuators B: Chemical2013,178, 663-670.10.1016/j.snb.2013.01.027]Search in Google Scholar
[82. Zheng, L. Y., et al., Electrochemical measurements of biofilm development using polypyrrole enhanced flexible sensors. Sensors and Actuators B: Chemical2013,182, 725-732.10.1016/j.snb.2013.03.097]Search in Google Scholar
[83. Ben-Yoav, H., et al., An electrochemical impedance model for integrated bacterial biofilms. Electrochimica Acta2011,56 (23), 7780-7786.10.1016/j.electacta.2010.12.025]Search in Google Scholar
[84. Wang, W., et al., Heterogeneous electrochemical characteristics of biofilm/metal interface and local electrochemical techniques used for this purpose. Materials and Corrosion2009,60 (12), 957-962.10.1002/maco.200905227]Search in Google Scholar
[85. Stoulil, J., et al., Corrosion resistance of new powder metallurgy boron-containing stainless steel in the nuclear repository environment. Materials and Corrosion2015,66 (4), 342-346.10.1002/maco.201307468]Search in Google Scholar
[86. Smart, N. R., et al. Galvanic corrosion of copper-cast iron couples; SKB Technical Report TR-05-06; 2005.]Search in Google Scholar
[87. Taxén, C. Possible effects of external electrical fields on the corrosion of copper in bentonite; SKB Technical Report P-11-43; 2011.]Search in Google Scholar
[88. Wang, W., et al., Electrochemical techniques used in MIC studies. Materials and Corrosion2006,57 (10), 800-804.10.1002/maco.200503966]Search in Google Scholar
[89. Xie, X. H., et al., EQCM and EIS Study of the Effect of Potential of Zero Charge on Escherichia Coli Biofilm Development. International Journal of Electrochemical Science2010,5, 1018 - 1025.]Search in Google Scholar
[90. Dheilly, A., et al., Monitoring of microbial adhesion and biofilm growth using electrochemical impedancemetry. Appl Microbiol Biotechnol2008,79 (1), 157-64.10.1007/s00253-008-1404-718330564]Search in Google Scholar
[91. Franklin, M. J., et al., Effect of Electrochemical Impedance Spectroscopy on Microbial Biofilm Cell Numbers, Viability, and Activity. Corrosion1991,47 (7), 519-522.10.5006/1.3585287]Search in Google Scholar
[92. Muñoz-Berbel, X., et al., Impedimetric approach for monitoring the formation of biofilms on metallic surfaces and the subsequent application to the detection of bacteriophages. Electrochimica Acta2008,53 (19), 5739-5744.10.1016/j.electacta.2008.03.050]Search in Google Scholar
[93. Zuo, R.; Wood, T. K., Inhibiting mild steel corrosion from sulfate-reducing and iron-oxidizing bacteria using gramicidin-S-producing biofilms. Appl Microbiol Biotechnol2004,65 (6), 747-53.10.1007/s00253-004-1651-115278311]Search in Google Scholar