W. Sand and E. Bock, Concrete corrosion in the Hamburg sewer system, Environ Technol Lett, vol.5, issue.12, pp.517-528, 1984.

A. Albrecht, A. Bertron, and M. Libert, Microbial catalysis of redox reactions in concrete cells of nuclear waste repositories: a review and introduction, pp.147-159, 2013.

A. Dubosc, G. Escadeillas, and P. J. Blanc, Characterization of biological stains on external concrete walls and influence of concrete as underlying material, Cem Concr Res, vol.31, issue.11, pp.1613-1617, 2001.
URL : https://hal.archives-ouvertes.fr/hal-02160788

M. Libert, M. K. Schütz, L. Esnault, D. Féron, and O. Bildstein, Impact of microbial activity on the radioactive waste disposal: long term prediction of biocorrosion processes, Bioelectrochemistry, vol.97, pp.162-168, 2014.

L. M. Prescott, J. P. Harley, and D. A. Klein, , 2003.

S. Juretschko, G. Timmermann, M. Schmid, K. Schleifer, A. Pommerening-röser et al., Combined molecular and conventional analyses of nitrifying bacterium diversity in activated sludge: Nitrosococcus mobilis and nitrospira-like bacteria as dominant populations, Appl Environ Microbiol, vol.64, issue.8, pp.3042-3051, 1998.

C. D. Parker, The corrosion of concrete-1. The isolation of a species of bacterium associated with the corrosion of concrete exposed to atmospheres containing hydrogen sulphide, Aust J Exp Biol Med Sci, vol.23, issue.2, pp.81-90, 1945.

C. D. Parker, The corrosion of concrete-2. The function of thiobacillus concretivorus (nov. Spec.) In the corrosion of concrete exposed to atmospheres containing hydrogen sulphide, Aust J Exp Biol Med Sci, vol.23, issue.2, pp.91-98, 1945.

R. Islander, J. Devinny, F. Mansfeld, A. Postyn, and H. Shih, Microbial ecology of crown corrosion in sewers, J Environ Eng, vol.117, issue.6, pp.751-770, 1991.

D. Roberts, D. Nica, G. Zuo, and J. Davis, Quantifying microbially induced deterioration of concrete: initial studies, Int Biodeterior Biodegrad, vol.49, issue.4, pp.227-234, 2002.

J. W. Costerton, Z. Lewandowski, D. Debeer, D. Caldwell, D. Korber et al., Biofilms, the customized microniche, J Bacteriol, vol.176, issue.8, pp.2137-2142, 1994.

D. G. Davies, M. R. Parsek, J. P. Pearson, B. H. Iglewski, J. W. Costerton et al., The involvement of cellto-cell signals in the development of a bacterial biofilm, Science, vol.280, issue.5361, pp.295-298, 1998.

T. F. Mah, O. Toole, and G. A. , Mechanisms of biofilm resistance to antimicrobial agents, Trends Microbiol, vol.9, issue.1, pp.34-39, 2001.

D. Wang, R. Cullimore, Y. Hu, and R. Chowdhury, Biodeterioration of asbestos cement (AC) pipe in drinking water distribution systems, Int Biodeterior Biodegrad, vol.14, issue.6, pp.810-817, 2011.

A. Leemann, B. Lothenbach, and C. Hoffmann, Biologically induced concrete deterioration in a wastewater treatment plant assessed by combining microstructural analysis with thermodynamic modeling, Cem Concr Res, vol.40, issue.8, pp.1157-1164, 2010.

A. Bertron, M. Coutand, X. Cameleyre, G. Escadeillas, and J. Duchesne, Attaques chimique et biologique des effluents agricoles et agroalimentaires sur les matériaux cimentaires, Matér Technol, vol.93, pp.111-121, 2006.

M. G. Alexander and C. Fourie, Performance of sewer pipe concrete mixtures with portland and calcium aluminate cements subject to mineral and biogenic acid attack, Mater Struct, vol.44, issue.1, pp.313-330, 2011.

N. De-belie, M. Richardson, C. R. Braam, B. Svennerstedt, J. J. Lenehan et al., Durability of building materials and components in the agricultural environment: part I, the agricultural environment and timber structures, J Agric Eng Res, vol.75, issue.3, pp.225-241, 2000.

T. Wells and R. E. Melchers, An observation-based model for corrosion of concrete sewers under aggressive conditions, Cem Concr Res, pp.61-62, 2014.

J. Herisson, E. D. Van-hullebusch, M. Moletta-denat, P. Taquet, and T. Chaussadent, Toward an accelerated biodeterioration test to understand the behavior of Portland and calcium aluminate cementitious materials in sewer networks, Int Biodeterior Biodegrad, vol.84, pp.236-243, 2013.
URL : https://hal.archives-ouvertes.fr/hal-00877540

T. Warscheid and J. Braams, Biodeterioration of stone: a review, Int Biodeterior Biodegrad, vol.46, issue.4, pp.343-368, 2000.

C. C. Gaylarde and L. Morton, Deteriogenic biofilms on buildings and their control: a review, Biofouling, vol.14, issue.1, pp.59-74, 1999.

, Performance of cement-based materials in aggressive aqueous environments, RILEM TC 211-PAE, 2013.

J. Duchesne and A. Bertron, Performance of cement-based materials in aggressive aqueous environments, pp.91-112, 2013.

E. Menéndez, T. Matschei, and F. P. Glasser, Performance of cement-based materials in aggressive aqueous environments, pp.7-74, 2013.

A. Bertron and J. Duchesne, Attack of cementitious materials by organic acids in agricultural and agrofood effluents, pp.131-173, 2013.

C. Magniont, M. Coutand, A. Bertron, X. Cameleyre, C. Lafforgue et al., A new test method to assess the bacterial deterioration of cementitious materials, Cem Concr Res, vol.41, issue.4, pp.429-438, 2011.
URL : https://hal.archives-ouvertes.fr/hal-02165383

J. Gu, T. E. Ford, N. S. Berke, and R. Mitchell, Biodeterioration of concrete by the fungus Fusarium, Int Biodeterior Biodegrad, vol.41, issue.2, pp.101-109, 1998.

V. Wiktor, P. Grosseau, R. Guyonnet, E. Garcia-diaz, and C. Lors, Accelerated weathering of cementitious matrix for the development of an accelerated laboratory test of biodeterioration, Mater Struct, vol.44, issue.3, pp.623-640, 2011.
URL : https://hal.archives-ouvertes.fr/hal-00542958

J. Johnson, Détérioration des silos-tours en béton. Ministère de l'Agriculture, de l'Alimentation et des Affaires Rurales Ontario, pp.8-058, 2008.

A. Bertron, Durabilité des matériaux cimentaires soumis aux acides organiques, Cas particulier des effluents d'e ´levage, 2004.

H. Barberousse, B. Ruot, C. Yéprémian, and G. Boulon, An assessment of façade coatings against colonisation by aerial algae and cyanobacteria, Build Environ, vol.42, issue.7, pp.2555-2561, 2007.

G. Escadeillas, A. Bertron, P. Blanc, and A. Dubosc, Accelerated testing of biological stain growth on external concrete walls. Part 1: development of the growth tests, Mater Struct, vol.40, issue.10, pp.1061-1071, 2007.
URL : https://hal.archives-ouvertes.fr/hal-02165388

G. Escadeillas, A. Bertron, E. Ringot, P. J. Blanc, and A. Dubosc, Accelerated testing of biological stain growth on external concrete walls. Part 2: quantification of growths, Mater Struct, vol.42, issue.7, pp.937-945, 2009.
URL : https://hal.archives-ouvertes.fr/hal-02165388

T. H. Tran, A. Govin, R. Guyonnet, P. Grosseau, C. Lors et al., Influence of the intrinsic characteristics of mortars on biofouling by Klebsormidium flaccidum, Int Biodeterior Biodegrad, vol.70, pp.31-39, 2012.
URL : https://hal.archives-ouvertes.fr/hal-00680295

T. H. Tran, A. Govin, R. Guyonnet, P. Grosseau, C. Lors et al., Influence of the intrinsic characteristics of mortars on their biofouling by pigmented organisms: Comparison between laboratory and field-scale experiments, Int Biodeterior Biodegrad, vol.86, pp.334-342, 2014.
URL : https://hal.archives-ouvertes.fr/hal-00908332

D. J. Giannantonio, J. C. Kurth, K. E. Kurtis, and P. A. Sobecky, Effects of concrete properties and nutrients on fungal colonization and fouling, Int Biodeterior Biodegrad, vol.63, issue.3, pp.252-259, 2009.

H. Barberousse, G. Tell, C. Yéprémian, and A. Couté, Diversity of algae and cyanobacteria growing on building façades in France, Algol Stud, vol.120, issue.1, pp.81-105, 2006.

C. C. Gaylarde and P. M. Gaylarde, A comparative study of the major microbial biomass of biofilms on exteriors of buildings in Europe and Latin America, Int Biodeterior Biodegrad, vol.55, issue.2, pp.131-139, 2005.

F. Rindi, Distribution and ecology of green algae and cyanobacteria in urban habitats, Seckbach DJ, pp.619-638, 2007.

D. J. Giannantonio, J. C. Kurth, K. E. Kurtis, and P. A. Sobecky, Molecular characterizations of microbial communities fouling painted and unpainted concrete structures, Int Biodeterior Biodegrad, vol.63, issue.1, pp.30-40, 2009.

D. Giovannacci, C. Leclaire, M. Horgnies, M. Ellmer, J. D. Mertz et al., Algal colonization kinetics on roofing and façade tiles: influence of physical parameters, Constr Build Mater, vol.48, pp.670-676, 2013.

T. Martinez, A. Bertron, G. Escadeillas, and E. Ringot, Algal growth inhibition on cement mortar: efficiency of water repellent and photocatalytic treatments under UV/ Vis illumination, Int. Biodeterior. Biodegrad, vol.89, pp.115-125, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01850753

A. Maury-ramirez, D. Muynck, W. Stevens, R. Demeestere, K. et al., Titanium dioxide based strategies to prevent algal fouling on cementitious materials, Cem Concr Compos, vol.36, pp.93-100, 2013.

, Materials and Structures

L. Graziani, E. Quagliarini, A. Osimani, L. Aquilanti, F. Clementi et al., Evaluation of inhibitory effect of TiO 2 nanocoatings against microalgal growth on clay brick façades under weak UV exposure conditions, Build Environ, vol.64, pp.38-45, 2013.

`. Urz?`curz?`urz?, D. Leo, and F. , Evaluation of the efficiency of water-repellent and biocide compounds against microbial colonization of mortars, Int Biodeterior Biodegrad, vol.60, issue.1, pp.25-34, 2007.

J. Macmullen, Z. Zhang, H. N. Dhakal, J. Radulovic, A. Karabela et al., Silver nanoparticulate enhanced aqueous silane/siloxane exterior facade emulsions and their efficacy against algae and cyanobacteria biofouling, Int Biodeterior Biodegrad, vol.93, pp.54-62, 2014.

S. Manso, D. Muynck, W. Segura, I. Aguado, A. Steppe et al., Bioreceptivity evaluation of cementitious materials designed to stimulate biological growth, Sci Total Environ, vol.481, pp.232-241, 2014.

T. Verdier, M. Coutand, A. Bertron, and C. Roques, A review of indoor microbial growth across building materials and sampling and analysis methods, Build Environ, vol.80, pp.136-149, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01850781

B. Gutarowska and M. Piotrowska, Methods of mycological analysis in buildings, Build Environ, vol.42, issue.4, pp.1843-1850, 2007.

D. Mudarri and W. J. Fisk, Public health and economic impact of dampness and mold, Indoor Air, vol.17, issue.3, pp.226-235, 2007.

M. A. Shirakawa, R. G. Tavares, C. C. Gaylarde, M. Taqueda, K. Loh et al., Climate as the most important factor determining anti-fungal biocide performance in paint films, Sci Total Environ, vol.408, issue.23, pp.5878-5886, 2010.

M. A. Shirakawa, C. C. Gaylarde, H. D. Sahão, and J. Lima, Inhibition of Cladosporium growth on gypsum panels treated with nanosilver particles, Int Biodeterior Biodegrad, vol.85, pp.57-61, 2013.

B. Gutarowska, K. Pietrzak, W. Machnowski, D. Danielewicz, M. Szynkowska et al., Application of silver nanoparticles for disinfection of materials to protect historical objects, Curr Nanosci, vol.10, issue.2, pp.277-286, 2014.

T. Verdier, M. Coutand, A. Bertron, and C. Roques, Antibacterial activity of TiO 2 photocatalyst alone or in coatings on E. coli: influence of methodological aspects, Coatings, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01850791

S. De-niederhãusern, M. Bondi, and F. Bondioli, Selfcleaning and antibacteric ceramic tile surface, Int J Appl Ceram Technol, vol.10, issue.6, pp.949-956, 2013.

R. Valentin, M. Alignan, G. Giacinti, F. Renaud, B. Raymond et al., Pure short-chain glycerol fatty acid esters and glycerylic cyclocarbonic fatty acid esters as surface active and antimicrobial coagels protecting surfaces by promoting superhydrophilicity, J Colloid Interface Sci, vol.365, issue.1, pp.280-288, 2012.
URL : https://hal.archives-ouvertes.fr/hal-01834905

M. I. Gomes, T. D. Gonçalves, and P. Faria, Earth-based repair mortars: experimental analysis with different binders and natural fibers, Rammed earth conservation, 2012.

B. A. Khan, P. Warner, and H. Wang, Antibacterial properties of hemp and other natural Fibre plants: a review, BioResources, vol.9, issue.2, pp.3642-3659, 2014.

F. Pacheco-torgal and S. Jalali, Earth construction: lessons from the past for future eco-efficient construction, Constr Build Mater, vol.29, pp.512-519, 2012.

C. Magniont, G. Escadeillas, M. Coutand, and C. Oms-multon, Use of plant aggregates in building ecomaterials, Eur J Environ Civ Eng, vol.16, issue.sup1, pp.17-33, 2012.
URL : https://hal.archives-ouvertes.fr/hal-02086524

F. Pacheco-torgal and S. Jalali, Cementitious building materials reinforced with vegetable fibres: a review, Constr Build Mater, vol.25, issue.2, pp.575-581, 2011.

Y. Millogo, J. Morel, A. Ghavami, and K. , Experimental analysis of pressed adobe blocks reinforced with Hibiscus cannabinus fibers, Constr Build Mater, vol.52, pp.71-78, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01850750

H. M. Jonkers, A. Thijssen, G. Muyzer, O. Copuroglu, and E. Schlangen, Application of bacteria as self-healing agent for the development of sustainable concrete, Ecol Eng, vol.36, issue.2, pp.230-235, 2010.

V. Wiktor and H. M. Jonkers, Quantification of crackhealing in novel bacteria-based self-healing concrete, Cem Concr Compos, vol.33, issue.7, pp.763-770, 2011.

W. De-muynck, D. Debrouwer, D. Belie, N. Verstraete, and W. , Bacterial carbonate precipitation improves the durability of cementitious materials, Cem Concr Res, vol.38, issue.7, pp.1005-1014, 2008.

K. Van-tittelboom, D. Belie, N. , D. Muynck, W. Verstraete et al., Use of bacteria to repair cracks in concrete, Cem Concr Res, vol.40, issue.1, pp.157-166, 2010.

N. D. Belie, Microorganisms versus stony materials: a love-hate relationship, Mater Struct, vol.43, issue.9, pp.1191-1202, 2010.

A. W. Decho, Overview of biopolymer-induced mineralization: What goes on in biofilms?, Ecol Eng, vol.36, issue.2, pp.137-144, 2010.

S. Soleimani, O. B. Isgor, and B. Ormeci, Resistance of biofilm-covered mortars to microbiologically influenced deterioration simulated by sulfuric acid exposure, Cem Concr Res, vol.53, pp.229-238, 2013.

S. Soleimani, B. Ormeci, and O. B. Isgor, Growth and characterization of Escherichia coli DH5a biofilm on concrete surfaces as a protective layer against microbiologically influenced concrete deterioration (MICD), Appl Microbiol Biotechnol, vol.97, issue.3, pp.1093-1102, 2013.

X. Ariño, J. Ortega-calvo, A. Gomezbolea, and C. Saizjimenez, Lichen colonization of the roman pavement at Baelo-Claudia (cadiz, Spain)-biodeterioration vs bioprotection, Sci Total Environ, vol.167, pp.353-363, 1995.

X. Ariño, A. Gomez-bolea, and C. Saiz-jimenez, Lichens on ancient mortars, Int Biodeterior Biodegrad, vol.40, issue.2-4, pp.217-224, 1997.

T. Mori, T. Nonaka, K. Tazaki, M. Koga, Y. Hikosaka et al., Interactions of nutrients, moisture and pH on microbial corrosion of concrete sewer pipes, Water Res, vol.26, issue.1, pp.29-37, 1992.

J. Herisson, E. Van-hullebusch, M. Guegen-minerbe, and T. Chaussadent, Biogenic corrosion mechanism: study of parameters explaining calcium aluminate cement durability, Presented at the International Conference on Calcium Aluminates, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01053359

P. Lavigne, M. Bertron, A. Auer, L. Hernandez-raquet, G. Foussard et al., , 2014.

A. Bertron, J. Duchesne, and G. Escadeillas, Durability of various binders exposed to organic acids in liquid manure, Seventh Canmet/ACI international conference on durability of concrete, 2007.

S. Larreur-cayol, A. Bertron, S. Nicolas, R. Escadeillas, and G. , Durability of different binders in synthetic agricultural effluents, Proceedings of the 7th international symposium on cement based materials for a sustainable agriculture; CIGR international symposium, pp.56-66, 2011.

A. Bertron, G. Escadeillas, P. De-parseval, and J. Duchesne, Processing of electron microprobe data from the analysis of altered cementitious materials, Cem Concr Res, vol.39, issue.10, pp.929-935, 2009.
URL : https://hal.archives-ouvertes.fr/hal-02165396

O. Oueslati and J. Duchesne, The effect of SCMs and curing time on resistance of mortars subjected to organic acids, Cem Concr Res, vol.42, issue.1, pp.205-214, 2012.

V. Pavlík, Corrosion of hardened cement paste by acetic and nitric acids part II: formation and chemical composition of the corrosion products layer, Cem Concr Res, vol.24, issue.8, pp.1495-1508, 1994.

A. Bertron, Performance of cement-based materials in aggressive aqueous environments, pp.355-387, 2013.

G. M. Gadd, Fungal production of citric and oxalic acid: importance in metal speciation, physiology and biogeochemical processes, Advances in microbial physiology, vol.41, pp.47-92, 1999.

H. S. Grewal and K. L. Kalra, Fungal production of citric acid, Biotechnol Adv, vol.13, issue.2, pp.209-234, 1995.

M. Monte, Oxalate film formation on marble specimens caused by fungus, J Cult Herit, vol.4, issue.3, pp.255-258, 2003.

M. A. De-la-torre, G. Gomez-alarcon, C. Vizcaino, and M. T. Garcia, Biochemical mechanisms of stone alteration carried out by filamentous fungi living in monuments, Biogeochemistry, vol.19, issue.3, pp.129-147, 1992.

S. Villar, H. Edwards, and M. Seaward, Lichen biodeterioration of ecclesiastical monuments in northern Spain, Spectrochim Acta A, vol.60, issue.5, pp.1229-1237, 2004.

B. Doherty, M. Pamplona, C. Miliani, M. Matteini, A. Sgamellotti et al., Durability of the artificial calcium oxalate protective on two Florentine monuments, J Cult Herit, vol.8, issue.2, pp.186-192, 2007.

L. De-windt and P. Devillers, Modeling the degradation of Portland cement pastes by biogenic organic acids, Cem Concr Res, vol.40, issue.8, pp.1165-1174, 2010.
URL : https://hal.archives-ouvertes.fr/hal-00557835

C. Shi and J. Stegemann, Acid corrosion resistance of different cementing materials, Cem Concr Res, vol.30, issue.5, pp.803-808, 2000.

E. Gruyaert, P. Van-den-heede, M. Maes, D. Belie, and N. , Investigation of the influence of blast-furnace slag on the resistance of concrete against organic acid or sulphate attack by means of accelerated degradation tests, Cem Concr Res, vol.42, issue.1, pp.173-185, 2012.

O. Oueslati and J. Duchesne, Resistance of blended cement pastes subjected to organic acids: quantification of anhydrous and hydrated phases, Cem Concr Compos, vol.45, pp.89-101, 2014.

S. Larreur-cayol, Attaques des matériaux cimentaires par les acides organiques des effluents agricoles et agro-alimentaires, 2012.

T. Bakharev, J. G. Sanjayan, and Y. Cheng, Resistance of alkali-activated slag concrete to acid attack, Cem Concr Res, vol.33, issue.10, pp.1607-1611, 2003.

S. A. Bernal, E. D. Rodríguez, R. De-mejía-gutiérrez, and J. L. Provis, Performance of alkali-activated slag mortars exposed to acids, J Sustain Cem-Based Mater, vol.1, issue.3, pp.138-151, 2012.

S. A. Bernal and J. L. Provis, Durability of alkali-activated materials: progress and perspectives, J Am Ceram Soc, vol.97, issue.4, pp.997-1008, 2014.

E. Sánchez, A. Moragues, J. Massana, A. Guerrero, and J. Fernandez, Effect of pig slurry on two cement mortars: changes in strength, porosity and crystalline phases, Cem Concr Res, vol.39, issue.9, pp.798-804, 2009.

W. De-muynck, A. M. Ramirez, N. De-belie, and W. Verstraete, Evaluation of strategies to prevent algal fouling on white architectural and cellular concrete, Int Biodeterior Biodegrad, vol.63, issue.6, pp.679-689, 2009.

V. Wiktor, D. Leo, F. Urz?`curz?`urz?, `. Guyonnet, R. Grosseau et al., Accelerated laboratory test to study fungal biodeterioration of cementitious matrix, Int Biodeterior Biodegrad, vol.63, issue.8, pp.1061-1065, 2009.
URL : https://hal.archives-ouvertes.fr/emse-00431106

P. Lavigne, M. Bertron, A. Botanch, C. Auer, L. Hernandez-raquet et al., An innovative approach to reproduce the biodeterioration of industrial cementitious products in a sewer environment. Part II: validation on CAC and BFSC linings, Cem Concr Res, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01849778

P. Lavigne, M. Bertron, A. Cockx, A. Foussard, J. Escadeillas et al., New method for evaluation of cement-based material resistance against biogenic attack in sewer-like environment: comparison between CAC and CEM III coatings, 2014.

A. Dossier, Argile, tome architecture et gestion du stockage géologique, Andra report C, 2005.

I. Walczak, M. Libert, S. Camaro, and J. M. Blanchard, Quantitative and qualitative analysis of hydrosoluble organic matter in bitumen leachates, Agronomie, vol.21, issue.3, pp.247-257, 2001.
URL : https://hal.archives-ouvertes.fr/hal-00886113

J. F. Devlin, R. Eedy, and B. J. Butler, The effects of electron donor and granular iron on nitrate transformation rates in sediments from a municipal water supply aquifer, J Contam Hydrol, vol.46, issue.1-2, pp.81-97, 2000.

M. Libert, O. Bildstein, L. Esnault, M. Jullien, and R. Sellier, Molecular hydrogen: an abundant energy source for bacterial activity in nuclear waste repositories, Phys. Chem. Earth Parts ABC, vol.36, pp.1616-1623, 2011.

L. Truche, G. Berger, A. Albrecht, and L. Domergue, Abiotic nitrate reduction induced by carbon steel and hydrogen: implications for environmental processes in waste repositories, Appl Geochem, vol.28, pp.155-163, 2013.
URL : https://hal.archives-ouvertes.fr/hal-01315515

S. Poulain, Caractérisation microbiologique de l'argile a ` Opalinus du Mont Terri et de l'argilite du Callovo-Oxfordien de Meuse/Haute-Marne, 2006.

S. Poulain, C. Sergeant, M. Simonoff, L. Marrec, C. Altmann et al., Microbial investigations in opalinus clay, an argillaceous formation under evaluation as a potential host rock for a radioactive waste repository, Geomicrobiol J, vol.25, issue.5, pp.240-249, 2008.

S. Stroes-gascoyne, A. Schippers, B. Schwyn, S. Poulain, C. Sergeant et al., Microbial community analysis of opalinus clay drill core samples from the Mont Terri Underground Research Laboratory, Geomicrobiol J, vol.24, issue.1, pp.1-17, 2007.
URL : https://hal.archives-ouvertes.fr/hal-00176818

S. Stroes-gascoyne, C. Sergeant, A. Schippers, C. J. Hamon, S. Nèble et al., Biogeochemical processes in a clay formation in situ experiment: part D-microbial analyses-synthesis of results, Appl Geochem, vol.26, issue.6, pp.980-989, 2011.
URL : https://hal.archives-ouvertes.fr/in2p3-00607073

A. J. Williamson, K. Morris, S. Shaw, J. M. Byrne, C. Boothman et al., Microbial reduction of Fe(III) under alkaline conditions relevant to geological disposal, Appl Environ Microbiol, vol.79, pp.3320-3326, 2013.

K. Pedersen, E. Nilsson, J. Arlinger, L. Hallbeck, O. Neill et al., Distribution, diversity and activity of microorganisms in the hyper-alkaline spring waters of Maqarin in Jordan, Extremophiles, vol.8, issue.2, pp.151-164, 2004.

R. A. Whittleston, D. I. Stewart, R. Mortimer, and I. T. Burke, Biostimulation of nitrate, iron and chromate reduction at hyperalkaline conditions, Geochim Cosmochim Acta, vol.73, p.1436, 2009.

M. Alquier, C. Kassim, A. Bertron, C. Sablayrolles, A. Albrecht et al., Halomonas desiderata as a bacterial model to predict the possible biological nitrate reduction in concrete cells of nuclear waste disposals, J Environ Manag, vol.132, pp.32-41, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01850764

A. Bertron, B. Erable, M. Alquier, N. Jacquemet, C. Kassim et al., Catalyse biotique et abiotique de la réduction des nitrates en milieu alcalin dans le contexte du stockage profond des déchets radioactifs, Matér Technol, vol.101, issue.1, p.104, 2013.

Y. Rafrafi, . Ranaivomananah, A. Bertron, A. Albrecht, and B. Erable, Abiotic and biotic reduction of nitrate at alkaline pH: conditions comparable to a nuclear waste repository, Int Biodeterior Biodegrad, 2014.

A. Bertron, N. Jacquemet, B. Erable, C. Sablayrolles, G. Escadeillas et al., Reactivity of nitrate and organic acids at the concrete-bitumen interface of a nuclear waste repository cell, Nucl Eng Des, vol.268, pp.51-57, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01850751

M. Fomina, V. S. Podgorsky, S. V. Olishevska, V. M. Kadoshnikov, I. R. Pisanska et al., Fungal deterioration of barrier concrete used in nuclear waste disposal, Geomicrobiol J, vol.24, issue.7-8, pp.643-653, 2007.

M. Wolf and R. Bachofen, Microbial legradation of bitumen, Experientia, vol.47, issue.6, pp.542-548, 1991.

R. Roffey and A. Norqvist, Biodegradation of bitumen used for nuclear waste disposal, Experientia, vol.47, issue.6, pp.539-542, 1991.

J. V. Perfettini, E. Revertegat, and N. Langomazino, Evaluation of cement degradation induced by the metabolic products of two fungal strains, Experientia, vol.47, issue.6, pp.527-533, 1991.

K. Pedersen, Microbial features, events and processes in the Swedish final repository for lowand intermediate-level radioactive waste (Project SAFE), 2001.

L. Newsome, K. Morris, and J. R. Lloyd, The biogeochemistry and bioremediation of uranium and other priority radionuclides, Chem Geol, vol.363, pp.164-184, 2014.
DOI : 10.1016/j.chemgeo.2013.10.034
URL : https://doi.org/10.1016/j.chemgeo.2013.10.034

M. Simonoff, C. Sergeant, S. Poulain, and M. S. Pravikoff, Microorganisms and migration of radionuclides in environment, Comptes Rendus Chim, vol.10, pp.1092-1107, 2007.
URL : https://hal.archives-ouvertes.fr/hal-00176797

A. Kagawa, M. Fukumoto, and K. Kawamura, Influence of chemical and radiolytic degradation of bitumen on its performance for disposal, J Nucl Sci Technol, vol.37, issue.10, pp.934-937, 2000.

M. Libert and I. Walczak, Effect of radio-oxidative ageing and pH on the release of soluble organic matter from bitumen, p.4, 2000.

L. R. Van-loon and Z. Kopajtic, Complexation of Cu 2? , Ni 2? and UO 22? by radiolytic degradation products of bitumen, 1990.

I. Walczak, Determination des produits organiques d'altérations chimiques et radiochimiques du bitume: applications aux enrobes bitumes, 2000.

S. Larreur-cayol, D. Windt, L. Bertron, A. Escadeillas, and G. , Deterioration of cementitious materials by organic acids in agricultural effluents: experiments and modelling. Presented at the 7th international symposium on cement based materials for a sustainable agriculture, pp.38-46, 2011.
URL : https://hal.archives-ouvertes.fr/hal-00669743

M. A. Glaus, L. R. Van-loon, S. Achatz, A. Chodura, and K. Fischer, Degradation of cellulosic materials under the alkaline conditions of a cementitious repository for low and intermediate level radioactive waste: part I: identification of degradation products, Anal Chim Acta, vol.398, issue.1, pp.111-122, 1999.

C. J. Knill and J. F. Kennedy, Degradation of cellulose under alkaline conditions, Carbohydr Polym, vol.51, issue.3, pp.281-300, 2003.
DOI : 10.1016/s0144-8617(02)00183-2

A. Bertron, H. Ranaivomanana, N. Jacquemet, B. Erable, C. Sablayrolles et al., Physicochemical interactions at the concrete-bitumen interface of nuclear waste repositories, EPJ Web Conf, vol.56, p.1002, 2013.
DOI : 10.1051/epjconf/20135601002
URL : https://hal.archives-ouvertes.fr/hal-00875261

L. Truche, Effet catalyt¡que des aciers et produits de corros¡on sur la réduction abiotique des nitrates par H 2 en condition de stockage MAVL-impact des fortes concentrations en nitrate et de la disponibilité des sites réactifs sur les aciers, Géoressources, 2013.

L. Truche, G. Berger, A. Albrecht, and L. Domergue, Engineered materials as potential geocatalysts in deep geological nuclear waste repositories: a case study of the stainless steel catalytic effect on nitrate reduction by hydrogen, Appl Geochem, vol.35, pp.279-288, 2013.
URL : https://hal.archives-ouvertes.fr/hal-01315514

N. M. Tiedje, Genetic engineering of symbiotic nitrogen fixation and conversation of fixed nitrogen, pp.481-497, 1981.

B. Erable, A. Bertron, Y. Rafrafi, C. Kassim, and A. Albrecht, Evaluation of microbial denitrifying kinetics by Halomonas desiderata in a continuous bioreactor simulating the alkaline conditions inside cement-based cell for nuclear waste disposal, Biotechnol Bioeng, 2014.

M. Libert, I. Pointeau, R. Sellier, M. Lillo, I. T. Burke et al., Nitrate reducing bacterial activity under alkaline conditions found in intermediate-level nuclear waste repositories, Presented at the 1st international symposium on cement-based materials for nuclear wastes NUWCEM, 2011.

Y. Rafrafi, H. Ranaivomanana, B. Erable, A. Bertron, C. Kassim et al., Bio-réactivité des nitrates en milieu cimentaire en présence de matière organique et/ou d'H2Exploitation du dispositif pilote et prise en compte de la corrosion, 2013.

A. Rizoulis, H. M. Steele, K. Morris, and J. R. Lloyd, The potential impact of anaerobic microbial metabolism during the geological disposal of intermediate-level waste, Miner Mag, vol.76, issue.8, pp.3261-3270, 2012.

F. Berendes, G. Gottschalk, E. Heine-dobbernack, E. Moore, and B. J. Tindall, Halomonas desiderata sp. nov, a new alkaliphilic, halotolerant and denitrifying bacterium isolated from a municipal sewage works, Syst Appl Microbiol, vol.19, issue.2, pp.158-167, 1996.

H. E. Arter, K. W. Hanselmann, and R. Bachofen, Modelling of microbial degradation processes: the behaviour ofmicroorganisms in a waste repository, Experientia, vol.47, issue.6, pp.578-583, 1991.

I. G. Mckinley and H. A. Grogan, Consideration of microbiology in modelling the near field of a L/ILW repository, Experientia, vol.47, issue.6, pp.573-577, 1991.

L. André, H. Pauwels, M. Dictor, M. Parmentier, and M. Azaroual, Experiments and numerical modelling of microbially-catalysed denitrification reactions, Chem Geol, vol.287, issue.3-4, pp.171-181, 2011.