M. L. Abel, K. Shimizu, M. Holliman, and J. F. Watts, Peak-fitting of high resolution ToF-SIMS spectra: a preliminary study, Surface and Interface Analysis, vol.41, pp.265-268, 2009.

P. Aharon and B. Fu, Microbial sulfate reduction rates and sulfur and oxygen isotope fractionations at oil and gas seeps in deepwater Gulf of Mexico, Geochimica et Cosmochimica Acta, vol.64, pp.233-246, 2000.

M. M. Al-darbi, K. Agha, and M. R. Islam, Comprehensive Modelling of the Pitting Biocorrosion of Steel, The Canadian Journal of Chemical Engineering, vol.83, pp.872-881, 2008.

R. L. Allen and W. J. Moore, Diffusion of Silver in Silver Sulfide, The Journal of Physical Chemistry, vol.63, pp.223-226, 1959.

P. Angell and K. Urbanic, Sulphate-reducing bacterial activity as a parameter to predict localized corrosion of stainless alloys, Corrosion Science, vol.42, pp.897-912, 2000.

G. Antler, A. V. Turchyn, V. Rennie, B. Herut, and O. Sivan, Coupled sulfur and oxygen isotope insight into bacterial sulfate reduction in the natural environment, Geochimica et Cosmochimica Acta, vol.118, pp.98-117, 2013.

W. E. Balch, G. E. Fox, L. J. Magrum, C. R. Woese, and R. S. Wolfe, Methanogens: Reevaluation of a Unique Biological Group, Microbiol.Rev, vol.43, p.37, 1979.

J. Bana?, B. Mazurkiewicz, W. Solarski, G. Palumbo, and U. Lelek-borkowska, Corrosion monitoring of the internal surfaces of tubing in shale gas wells, OCHRONA PRZED KOROZJ?, vol.1, pp.14-19, 2016.

M. Baroni, Etude des anomalies isotopiques du soufre et de l'oxygène dans le sulfate d'origine volcanique enregistré dans les archives glaciaires, 2006.

I. Grenoble,

G. Beamson, High resolution XPS of organic polymers. The Scienta ESCA 300 Database, 1992.

G. Beaudoin, B. E. Taylor, D. Rumble, and M. Thiemens, Variations in the sulfur isotope composition of troilite from the Cañon Diablo iron meteorite, Geochimica et Cosmochimica Acta, vol.58, pp.4253-4255, 1994.

I. Beech, A. Bergel, A. Mollica, H. Flemming, V. Scotto et al., Simple Methods for the Investigation of the Role of Biofilms in Corrosion, Brite Euram Thematic Network on MIC of Industrial Materials, Task Group1, Biofilm Fundamentals, 2000.

I. B. Beech, Corrosion of technical materials in the presence of biofilms-current understanding and state-of-the art methods of study, International Biodeterioration & Biodegradation, vol.53, pp.177-183, 2004.

I. B. Beech, The potential use of atomic force microscopy for studying corrosion of metals in the presence of bacterial biofilms -an overview, International Biodeterioration & Biodegradation, vol.37, pp.141-149, 1996.

I. B. Beech and C. W. Cheung, Interactions of exopolymers produced by sulphate-reducing bacteria with metal ions, International Biodeterioration & Biodegradation, vol.35, pp.59-72, 1995.

I. B. Beech and C. C. Gaylarde, Recent advances in the study of biocorrosion: an overview, Revista de Microbiologia, vol.30, pp.117-190, 1999.

I. B. Beech and J. Sunner, Biocorrosion: towards understanding interactions between biofilms and metals, Current Opinion in Biotechnology, vol.15, pp.181-186, 2004.

H. E. Bennett, R. L. Peck, D. K. Burge, and J. M. Bennett, Formation and Growth of Tarnish on Evaporated Silver Films, Journal of Applied Physics, vol.40, pp.3351-3360, 1969.

L. G. Benning, R. T. Wilkin, and H. Barnes, Reaction pathways in the Fe-S system below 100°C, Chemical Geology, vol.167, pp.25-51, 2000.

R. A. Berner, Sedimentary pyrite formation, American Journal of Science, vol.268, pp.1-23, 1970.

R. A. Berner, Tetragonal Iron Sulfide. Science, vol.137, pp.669-669, 1962.

I. N. Bindeman, C. C. Lundstrom, C. Bopp, and F. Huang, Stable isotope fractionation by thermal diffusion through partially molten wet and dry silicate rocks, Earth and Planetary Science Letters, vol.365, pp.51-62, 2013.

V. I. Birss and G. A. Wright, The kinetics of the anodic formation and reduction of phase silver sulfide films on silver in aqueous sulfide solutions, Electrochimica Acta, vol.26, pp.1809-1817, 1981.

G. Bourat, Fermentations Propriétés des micro-organismes, 1992.

J. Bourdoiseau, Rôle des espèces sulfures sur le comportement d'un acier non allié en milieu de stockage des déchets radioactifs de type C: interactions sulfures / produits de corrosion, 2011.

J. Bourdoiseau, M. Jeannin, R. Sabot, C. Rémazeilles, and P. Refait, Characterisation of mackinawite by Raman spectroscopy: Effects of crystallisation, drying and oxidation, Corrosion Science, vol.50, pp.3247-3255, 2008.

S. Boursiquot, M. Mullet, M. Abdelmoula, J. Génin, and J. Ehrhardt, The dry oxidation of tetragonal FeS 1-x mackinawite, Physics and Chemistry of Minerals, vol.28, pp.600-611, 2001.
URL : https://hal.archives-ouvertes.fr/hal-02046727

M. Bouttemy, S. Grousset, F. Mercier-bion, D. Neff, A. Etcheberry et al., Multitechnique investigation of sulfur phases in the corrosion product layers of iron corroded in long-term anoxic conditions: From micrometer to nanometer scale, Surface and Interface Analysis, 2018.
URL : https://hal.archives-ouvertes.fr/cea-01858461

B. Brunner and S. M. Bernasconi, A revised isotope fractionation model for dissimilatory sulfate reduction in sulfate reducing bacteria, Geochimica et Cosmochimica Acta, vol.69, pp.4759-4771, 2005.

V. F. Buchwald, Handbook of iron meteorites, 1975.

A. N. Buckley and R. Woods, The surface oxidation of pyrite, Applied Surface Science, vol.27, pp.437-452, 1987.

A. N. Buckley, H. J. Wouterlood, and R. Woods, The interaction of pyrite with solutions containing silver ions, Journal of Applied Electrochemistry, vol.19, pp.744-751, 1989.

B. Buhn, R. V. Santos, M. A. Dardenne, and C. G. De-oliveira, Mass-dependent and massindependent sulfur isotope fractionation (34S and 33S) from Brazilian Archean and Proterozoic sulfide deposits by laser ablation multi-collector ICP-MS, Chemical Geology, pp.163-176, 2012.

X. Campaignolle, Étude des facteurs de risque de la corrosion bactérienne des aciers au carbone induite par les bactéries anaérobies sulfurogènes, 1996.

W. E. Campbell and U. B. Thomas, Tarnish studies the electrolytic reduction method for the analysis of films on metal surfaces, Transactions of the Electrochemical Society, vol.76, pp.303-328, 1939.

D. E. Canfield, Isotope fractionation by natural populations of sulfate-reducing bacteria, Geochimica et Cosmochimica Acta, vol.65, pp.1117-1124, 2001.

D. E. Canfield, C. A. Olesen, and R. P. Cox, Temperature and its control of isotope fractionation by a sulfate-reducing bacterium, Geochimica et Cosmochimica Acta, vol.70, pp.548-561, 2006.

D. E. Canfield, R. Raiswell, and S. H. Bottrell, The reactivity of sedimentary iron minerals toward sulfide, American Journal of Science, vol.292, pp.659-683, 1992.

W. Cao and H. E. Elsayed-ali, Stability of Ag nanoparticles fabricated by electron beam lithography, Materials Letters, vol.63, pp.2263-2266, 2009.

W. W. Carothers, L. H. Adami, and R. J. Rosenbauer, Experimental oxygen isotope fractionation between siderite-water and phosphoric acid liberated CO2-siderite, 1988.

, Geochimica et Cosmochimica Acta, vol.52, pp.2445-2450

H. Castaneda and X. D. Benetton, SRB-biofilm influence in active corrosion sites formed at the steel-electrolyte interface when exposed to artificial seawater conditions, Corrosion Science, vol.50, pp.1169-1183, 2008.

L. A. Chambers and P. A. Trudinger, Microbiological fractionation of stable sulfur isotopes: A review and critique, Geomicrobiology Journal, vol.1, pp.249-293, 1979.

C. Chautard, Interactions fer/argile en conditions de stockage géologique profond : Impact d'activités bactériennes et d'hétérogénéités. Ecole nationale supérieure des mines de Paris, 2013.

J. Chivot, Fonctions thermodynamiques, diagramme de solubilité, diagramme E-pH des systèmes Fe-H2O, Fe-CO2-H2O, Fe-S H2O, Cr-H2Oet Ni-H2O en fonction de la température. Andra, Sciences et techniques, 2004.

C. Chu, P. D. Fuqua, and J. D. Barrie, Corrosion characterization of durable silver coatings by electrochemical impedance spectroscopy and accelerated environmental testing, Applied Optics, vol.45, p.1583, 2006.

B. H. Chudnovsky, Degradation of power contacts in industrial atmosphere: silver corrosion and whiskers, Proceedings of the Forty-Eighth IEEE Holm Conference On. IEEE, pp.140-150, 2002.

R. Collongues, J. Bénard, and P. Pascal, Nouveau traité de chimie minérale, 1957.

R. H. Condit, R. R. Hobbins, and C. E. Birchenall, Self-diffusion of iron and sulfur in ferrous sulfide, Oxidation of Metals, vol.8, pp.409-455, 1974.

T. B. Coplen, Guidelines and recommended terms for expression of stable-isotope-ratio and gas-ratio measurement results: Guidelines and recommended terms for expressing stable isotope results, Rapid Communications in Mass Spectrometry, vol.25, pp.2538-2560, 2011.

C. Corbella, E. Bertran, M. C. Polo, E. Pascual, and J. L. Andújar, Structural effects of nanocomposite films of amorphous carbon and metal deposited by pulsed-DC reactive magnetron sputtering, Diamond and Related Materials, vol.16, pp.1828-1834, 2007.

J. A. Costello, Cathodic depolarization by sulfate-reducing bacteria, South African Journal of Science, vol.70, pp.202-204, 1974.

J. W. Costerton, Z. Lewandowski, D. E. Caldwell, D. R. Korber, and H. M. Lappin-scott, Annual review of microbiology, Microbial Biofilms, vol.49, pp.711-745, 1995.

C. Cote, O. Rosas, M. Sztyler, J. Doma, I. Beech et al., Corrosion of low carbon steel by microorganisms from the 'pigging' operation debris in water injection pipelines, Bioelectrochemistry, vol.97, pp.97-109, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01878770

I. Couchoud, Les isotopes stables de l'oxygène et du carbone dans les spéléothèmes : des archives paléoenvironnementales, pp.275-291, 2008.

J. Crank, The mathematics of diffusion, 1975.

R. E. Criss, Principles of stable isotope distribution, 1999.

J. L. Crolet, From biology and corrosion to biocorrosion, Oceanologica Acta, vol.15, pp.87-94, 1992.

A. W. Czanderna, The adsorption of oxygen on silver, The Journal of Physical Chemistry, vol.68, pp.2765-2771, 1964.

C. Dagbert, Biocorrosion. Techniques de l'ingénieur. Corrosion vieillissement, 2009.
URL : https://hal.archives-ouvertes.fr/hal-01253091

M. De-romero, The mechanism of SRB action in MIC, based on sulfide corrosion and iron sulfide corrosion products, CORROSION 2005. NACE International, 2005.

F. Demoisson, M. Mullet, and B. Humbert, Investigation of pyrite oxidation by hexavalent chromium: Solution species and surface chemistry, Journal of Colloid and Interface Science, vol.316, pp.531-540, 2007.
URL : https://hal.archives-ouvertes.fr/hal-01848951

J. S. Depelteau, S. Brenzinger, and A. Briegel, Bacterial and Archaeal Cell Structure, Reference Module in Life Sciences, 2019.

J. Detmers, V. Bruchert, K. S. Habicht, and J. Kuever, Diversity of Sulfur Isotope Fractionations by Sulfate-Reducing Prokaryotes, Applied and Environmental Microbiology, vol.67, pp.888-894, 2001.

T. Ding, R. Bai, Y. Li, D. Wan, X. Zou et al., , p.32, 1999.

, S/34 S ratio of IAEA-S-1 reference material and V-CDT sulfur isotope standard, Science in China Series D: Earth Sciences, vol.42, pp.45-51

T. Ding, S. Valkiers, H. Kipphardt, P. De-bièvre, P. D. Taylor et al., Calibrated sulfur isotope abundance ratios of three IAEA sulfur isotope and late Main Stage base-metal mineral deposits, Montana. Chemical Geology, vol.215, pp.61-93, 2001.

H. Fischmeister and J. Drott, Reaction rate and growth forms of reaction product in the system Ag-H2S, Acta Metallurgica, vol.7, pp.777-781, 1959.

H. Flemming and J. Wingender, The biofilm matrix, Nature reviews microbiology, vol.8, p.623, 2010.

H. Flemming, J. Wingender, U. Szewzyk, P. Steinberg, S. A. Rice et al., Biofilms: an emergent form of bacterial life, Nature Reviews Microbiology, vol.14, p.563, 2016.

J. P. Franey, G. W. Kammlott, and T. E. Graedel, The corrosion of silver by atmospheric sulfurous gases, Corrosion Science, vol.25, pp.133-143, 1985.

W. H. Furry, R. C. Jones, and L. Onsager, On the Theory of Isotope Separation by Thermal Diffusion, Physical Review, vol.55, pp.1083-1095, 1939.

A. Galtayries, C. Cousi, S. Zanna, and P. Marcus, SO2 adsorption at room temperature on Ni(111) surface studied by XPS, Surface and Interface Analysis, vol.36, pp.997-1000, 2004.

X. Gao, S. Wang, J. Li, Y. Zheng, R. Zhang et al., Study of structure and optical properties of silver oxide films by ellipsometry, XRD and XPS methods, Thin Solid Films, pp.438-442, 2004.

T. E. Graedel, Corrosion Mechanisms for Silver Exposed to the Atmosphere, Journal of The Electrochemical Society, vol.139, 1963.

C. Gram, Ueber die isolirte Farbung der Schizomyceten in Schnitt-und Trockenpraparaten, Fortschritte der Medicin, vol.2, pp.185-189, 1884.

E. C. Greco and W. B. Wright, Corrosion of Iron in an H2S-CO2-H2O System, Corrosion, vol.18, pp.119-124, 1962.

S. Grousset, Détermination de la composition isotopique du soufre pour l'étude de l'origine, biotique ou abiotique, des sulfures de fer en corrosion anoxique, 2017.

S. Grousset, M. Bayle, A. Dauzeres, D. Crusset, V. Deydier et al., Study of iron sulphides in long-term iron corrosion processes: Characterisations of archaeological artefacts, Corrosion Science, vol.112, pp.264-275, 2016.
URL : https://hal.archives-ouvertes.fr/cea-01377025

S. Grousset, S. Mostefaoui, C. Chautard, A. Dauzeres, D. Crusset et al., Détermination de la bio-origine des sulfures de fer présents dans les systèmes de corrosion anoxiques par analyse de la composition isotopique du soufre en nanoSIMS, Matériaux & Techniques, vol.104, p.509, 2016.

K. Hallett, D. Thickett, D. S. Mcphail, and R. J. Chater, Application of SIMS to silver tarnish at the British Museum, Applied surface science, vol.203, pp.789-792, 2003.

W. A. Hamilton, Microbially influenced corrosion as a model system for the study of metal microbe interactions: a unifying electron transfer hypothesis, Biofouling, vol.19, pp.65-76, 2003.

W. A. Hamilton, Sulphate-Reducing Bacteria and Anaerobic Corrosion, Annual Review of Microbiology, vol.39, pp.195-217, 1985.

P. Harding, Uranium enrichment, in: Uranium for Nuclear Power, pp.321-351, 2016.

N. G. Harmandas and P. G. Koutsoukos, The formation of iron(II) sulfides in aqueous solutions, Journal of Crystal Growth, vol.167, pp.719-724, 1996.

A. G. Harrison and H. G. Thode, Mechanism of the bacterial reduction of sulphate from isotope fractionation studies, Transactions of the Faraday Society, vol.54, p.84, 1958.

A. G. Harrison and H. G. Thode, The kinetic isotope effect in the chemical reduction of sulphate, Transactions of the Faraday Society, vol.53, 1648.

D. W. Hatchett, X. Gao, S. W. Catron, and H. S. White, Evidence for a concentration-and potential-dependent surface-phase transition, The Journal of Physical Chemistry, vol.100, pp.331-338, 1996.

M. H. Hebb, Electrical Conductivity of Silver Sulfide, The Journal of Chemical Physics, vol.20, pp.185-190, 1952.

E. Heitz, H. Flemming, and W. Sand, Microbially influenced corrosion of materials: scientific and engineering aspects, 1996.

J. O. Hirschfelder, C. F. Curtiss, R. B. Bird, and M. G. Mayer, Molecular theory of gases and liquids, 1954.

J. Hoefs, Stable isotope geochemistry, 2009.

F. Huang, C. C. Lundstrom, J. Glessner, A. Ianno, A. Boudreau et al., Chemical and isotopic fractionation of wet andesite in a temperature gradient: Experiments and models suggesting a new mechanism of magma differentiation, Geochimica et Cosmochimica Acta, vol.73, pp.729-749, 2009.

S. Hunger and L. G. Benning, Greigite: a true intermediate on the polysulfide pathway to pyrite, International Atomic Energy Agency, 1993. Reference and intercomparison materials for stable isotopes of light elements 159, vol.8, 2007.

Z. A. Iofa, V. V. Batrakov, and . Cho-ngok-ba, Influence of anion adsorption on the action of inhibitors on the acid corrosion of iron and cobalt, Electrochimica Acta, vol.9, pp.1645-1653, 1964.

W. P. Iverson and G. J. Olson, Anaerobic corrosion by sulfate-reducing bacteria due to a highly-reactive volatile phosphorus compound. Final report, 1983.

R. Javaherdashti, How corrosion affects industry and life, Anti-Corrosion Methods and Materials, vol.47, pp.30-34, 2000.

M. L. Jensen and N. Nakai, Sulfur isotope meteorite standards, results and recommendations. Biogeochemistry of Sulfur Isotopes 35, 1962.

L. J. Jones, R. Carballido-lópez, and J. Errington, Control of cell shape in bacteria: helical, actin-like filaments in Bacillus subtilis, Cell, vol.104, pp.913-922, 2001.

R. C. Jones and W. H. Furry, The Separation of Isotopes by Thermal Diffusion, Reviews of Modern Physics, vol.18, pp.151-224, 1946.

S. Kakooei, M. C. Ismail, and B. Ariwahjoedi, Mechanisms of microbiologically influenced corrosion: a review, World Appl. Sci. J, vol.17, p.524, 2012.

I. R. Kaplan and S. C. Rittenberg, Microbiological Fractionation of Sulphur Isotopes, Journal of General Microbiology, vol.34, pp.195-212, 1964.

S. Kasukabe, Growth mechanism and growth form of ?-Ag2S whiskers, Journal of Crystal Growth, vol.65, pp.384-390, 1983.

V. K. Kaushik, XPS core level spectra and Auger parameters for some silver compounds, Journal of Electron Spectroscopy and Related Phenomena, vol.56, pp.273-277, 1991.

C. Kendall and E. A. Caldwell, Fundamentals of isotope geochemistry, in: Isotope Tracers in Catchment Hydrology, pp.51-86, 1998.

J. Kendall, SEPARATION OF ISOTOPES AND THERMAL DIFFUSION*, Nature, vol.150, pp.136-140, 1942.

H. Kim, Corrosion process of silver in environments containing 0.1 ppm H2S and 1.2 ppm NO2, Materials and Corrosion, vol.54, pp.243-250

R. A. King, J. D. Miller, and D. S. Wakerley, Corrosion of mild steel in cultures of sulphate-reducing bacteria: Effect of changing the soluble iron concentration during growth, British Corrosion Journal, vol.8, pp.89-93, 1973.

N. T. Kita, J. M. Huberty, R. Kozdon, B. L. Beard, and J. W. Valley, High-precision SIMS oxygen, sulfur and iron stable isotope analyses of geological materials: accuracy, surface topography and crystal orientation, Surface and Interface Analysis, vol.43, pp.427-431, 2011.

N. T. Kita, T. Ushikubo, B. Fu, and J. W. Valley, High precision SIMS oxygen isotope analysis and the effect of sample topography, Chemical Geology, vol.264, pp.43-57, 2009.

J. Kittel, F. Ropital, F. Grosjean, E. M. Sutter, and B. Tribollet, Corrosion mechanisms in aqueous solutions containing dissolved H2S. Part 1: Characterisation of H2S reduction on a 316L rotating disc electrode, Corrosion Science, vol.66, pp.324-329, 2013.
URL : https://hal.archives-ouvertes.fr/hal-00743214

C. Kleber, U. Hilfrich, and M. Schreiner, In situ investigations of the interaction of small inorganic acidifying molecules in humidified air with polycrystalline metal surfaces by means of TM-AFM, IRRAS, and QCM. Surface and Interface Analysis: An International Journal devoted to the development and application of techniques for the analysis of surfaces, vol.39, pp.702-710, 2007.

C. Kleber, R. Wiesinger, J. Schnöller, U. Hilfrich, H. Hutter et al., Initial oxidation of silver surfaces by S2? and S4+ species, Corrosion Science, vol.50, pp.1112-1121, 2008.

F. C. Kracek, Phase relations in the system sulfur-Silver and the transitions in silver sulfide, American Geophysical Union, vol.27, p.364, 1946.

V. W. Kuehr and V. Vlugt, The graphitization of cast iron as an electrochemical process in anaerobic soils, Water, vol.18, pp.147-165, 1934.

L. A. Kulakov, M. B. Mcalister, K. L. Ogden, M. J. Larkin, and J. F. O'hanlon, Analysis of bacteria contaminating ultrapure water in industrial systems, Applied and environmental microbiology, vol.68, pp.1548-1555, 2002.

J. Kvarekval, R. Nyborg, and H. Choi, Formation of multilayer iron sulfide films during high temperature CO2/H2S corrosion of carbon steel, 2003.

H. Kwart, Temperature dependence of the primary kinetic hydrogen isotope effect as a mechanistic criterion, Accounts of Chemical Research, vol.15, pp.401-408, 1982.

D. Landolt, Corrosion et chimie de surface des metaux, 1993.

H. Lappin-scott, S. Burton, and P. Stoodley, Revealing a world of biofilms-the pioneering research of Bill Costerton, Nature Reviews Microbiology, vol.12, p.781, 2014.

J. I. Lee, S. M. Howard, J. J. Kellar, K. N. Han, and W. Cross, Electrochemical interaction between silver and sulfur in sodium sulfide solutions, Metallurgical and materials transactions B, vol.32, pp.895-901, 2001.

A. R. Lennie and D. J. Vaughan, Spectroscopic studies of iron sulfide formation and phase relations at low temperatures. Mineral Spectroscopy: A Tribute to Roger G, 1996.

Z. Lewandowskiy, W. Dickinsony, and W. Leey, Electrochemical interactions of biofilms with metal surfaces, Water science and Technology, vol.36, pp.295-302, 1997.

N. Li, Mécanismes de corrosion des couches minces d'argent en milieu sulfuré, 2012.

N. Li, V. Maurice, L. H. Klein, and P. Marcus, Structure and Morphology Modifications of Silver Surface in the Early Stages of Sulfide Growth in Alkaline Solution, The Journal of Physical Chemistry C, vol.116, pp.7062-7072, 2012.

S. Y. Li, Y. G. Kim, K. S. Jeon, and Y. T. Kho, Microbiologically influenced corrosion of underground pipelines under the disbonded coatings, Metals and Materials, vol.6, pp.281-286, 2000.

E. Limam, Etude des mécanismes de dégradation de couches minces d'argent protégées par un revêtement d'oxyde, 2016.

E. Limam, V. Maurice, A. Seyeux, S. Zanna, L. H. Klein et al., Role of SiC substrate surface on local tarnishing of deposited silver mirror stacks, Applied Surface Science, vol.436, pp.1147-1156, 2018.
URL : https://hal.archives-ouvertes.fr/hal-02354438

E. Limam, V. Maurice, A. Seyeux, S. Zanna, L. H. Klein et al., Local Degradation Mechanisms by Tarnishing of Protected Silver Mirror Layers Studied by Combined Surface Analysis, The Journal of Physical Chemistry B, vol.122, pp.578-586, 2018.
URL : https://hal.archives-ouvertes.fr/hal-02354495

E. Limam, V. Maurice, A. Seyeux, S. Zanna, L. H. Klein et al., Role of SiC substrate surface on local tarnishing of deposited silver mirror stacks, Applied Surface Science, vol.436, pp.1147-1156, 2018.
URL : https://hal.archives-ouvertes.fr/hal-02354438

B. Little and P. Wagner, Myths related to microbiologically influenced corrosion, Materials, vol.36, 1997.

B. Little and P. Wagner, An overview of microbiologically influenced corrosion of metals and alloys used in the storage of nuclear wastes, Canadian Journal of Microbiology, vol.42, pp.367-374, 1996.

B. J. Little, T. L. Gerke, R. I. Ray, and J. S. Lee, The Mineralogy of Microbiologically Influenced Corrosion, Mineral Scales and Deposits, pp.107-122, 2015.

B. J. Little and J. S. Lee, Microbiologically influenced corrosion, Wiley series in corrosion, 2007.

C. Lors, F. Feugeas, and B. Tribollet, Interactions Matériaux-Microorganismes : Bétons et métaux plus résistants à la biodétérioration, 2017.

J. Macnamara and H. G. Thode, Comparison of the Isotopic Constitution of Terrestrial and Meteoritic Sulfur, Physical Review, vol.78, pp.307-308, 1950.

R. Marchal, Rôle des bactéries sulfurogènes dans la corrosion du fer, Oil & Gas Science and Technology, vol.54, pp.649-659, 1999.

A. Marietou, H. Røy, B. B. Jørgensen, and K. U. Kjeldsen, Sulfate Transporters in Dissimilatory Sulfate Reducing Microorganisms: A Comparative Genomics Analysis, Frontiers in Microbiology, vol.9, 2018.

R. L. Martin and R. R. Annand, Accelerated corrosion of steel by suspended iron sulfides in brine, Corrosion, vol.37, pp.297-301, 1981.

M. Mehanna, Mécanismes de transfert direct en corrosion microbienne des aciers : Application à Geobacter sulfurreducens et à l'hydrogénase de Clostridium acetobutylicum, 2009.

M. Millet, Mécanismes de corrosion haute température d'aciers par des acides naphténiques. Pierre et Marie Curie, 2013.

D. Minzari, M. S. Jellesen, P. Møller, and R. Ambat, Morphological study of silver corrosion in highly aggressive sulfur environments, Engineering failure analysis, vol.18, pp.2126-2136, 2011.

D. Monroe, Looking for chinks in the armor of bacterial biofilms, PLoS biology, vol.5, p.307, 2007.

M. A. Morris, M. Bowker, and D. A. King, Chapter 1 Kinetics of Adsorption, Desorption and Diffusion at Metal Surfaces, in: Comprehensive Chemical Kinetics, pp.1-179, 1984.

J. Morse, F. Millero, J. Cornwell, and D. Rickard, The chemistry of the hydrogen sulfide and iron sulfide systems in natural waters, Earth-Science Reviews, vol.24, pp.1-42, 1987.

J. F. Moulder and J. Chastain, Handbook of X-ray photoelectron spectroscopy: a reference book of standard spectra for identification and interpretation of XPS data, Update. ed. Perkin-Elmer Corporation, 1992.

R. M. Nix, An introduction to surface chemistry, 2003.

D. Peschanski, Détermination de coefficients d'autodiffusion par la méthode des échanges isotopiques-II. -Autodiffusion des ions S-et Ag+ dans le sulfure d'argent ?, Journal de Chimie Physique, vol.47, pp.933-941, 1950.

O. E. Petrova and K. Sauer, Escaping the biofilm in more than one way: desorption, detachment or dispersion. Current opinion in microbiology, vol.30, pp.67-78, 2016.

N. Pfennig, F. Widdel, and H. G. Trüper, The Dissimilatory Sulfate-Reducing Bacteria, The Prokaryotes, 1981.

H. Springer-berlin, , pp.926-940

V. A. Phillips, Role of Defects in Evaporated Silver Films on the Nucleation of Sulfide``Patches'', Journal of Applied Physics, vol.33, pp.712-717, 1962.

D. Pope, H. R. Gibbens, and R. L. Moss, The tarnishing of Ag at naturally-occurring H2S and SO2 levels, Corrosion Science, vol.8, pp.883-887, 1968.

D. Pope and R. L. Moss, The effect of iron inclusions on the sulphiding of silver foil, Corrosion Science, vol.5, pp.773-777, 1965.

J. R. Postgate, The sulphate-reducing bacteria, CUP Archive, 1979.

A. .. Pratt, I. .. Muir, and H. Nesbitt, X-ray photoelectron and Auger electron spectroscopic studies of pyrrhotite and mechanism of air oxidation, Geochimica et Cosmochimica Acta, vol.58, pp.827-841, 1994.

F. T. Price and Y. N. Shieh, Fractionation of sulfur isotopes during laboratory synthesis of pyrite at low temperatures, Chemical Geology, vol.27, pp.245-253, 1979.

R. Rabus, T. A. Hansen, and F. Widdel, Dissimilatory Sulfate-and Sulfur-Reducing Prokaryotes, The Prokaryotes, pp.309-404, 2013.

C. E. Rees, A steady-state model for sulphur isotope fractionation in bacterial reduction processes, Geochimica et Cosmochimica Acta, vol.37, pp.1141-1162, 1973.

C. Rémazeilles, D. Neff, F. Kergourlay, E. Foy, E. Conforto et al., Mechanisms of long-term anaerobic corrosion of iron archaeological artefacts in seawater, Corrosion Science, vol.51, pp.2932-2941, 2009.

C. Rémazeilles, M. Saheb, D. Neff, E. Guilminot, K. Tran et al., Microbiologically influenced corrosion of archaeological artefacts: characterisation of iron(II) sulfides by Raman spectroscopy, Journal of Raman Spectroscopy, vol.41, pp.1425-1433, 2010.

D. W. Rice, R. J. Cappell, W. Kinsolving, and J. Laskowski, Indoor corrosion of metals, Journal of the Electrochemical Society, vol.127, pp.891-901, 1980.

D. W. Rice, P. Peterson, E. B. Rigby, P. B. Phipps, R. J. Cappell et al., Atmospheric corrosion of copper and silver, Journal of the Electrochemical Society, vol.128, pp.275-284, 1981.

F. M. Richter, E. B. Watson, R. A. Mendybaev, F. Teng, and P. E. Janney, Magnesium isotope fractionation in silicate melts by chemical and thermal diffusion, Geochimica et Cosmochimica Acta, vol.72, pp.206-220, 2008.

D. Rickard and G. W. Luther, Chemistry of Iron Sulfides, Chemical Reviews, vol.107, pp.514-562, 2007.

D. Rickard and G. W. Luther, Kinetics of pyrite formation by the H2S oxidation of iron (II) monosulfide in aqueous solutions between 25 and 125°C: The mechanism, Geochimica et Cosmochimica Acta, vol.61, pp.135-147, 1997.

M. Robineau, A. Romaine, R. Sabot, M. Jeannin, V. Deydier et al., Galvanic corrosion of carbon steel in anoxic conditions at 80° C associated with a heterogeneous magnetite (Fe3O4)/mackinawite (FeS) layer, Electrochimica Acta, vol.255, pp.274-285, 2017.
URL : https://hal.archives-ouvertes.fr/hal-02478192

A. Romaine, Rôle des espèces sulfures dans la corrosion des aciers non alliés: hétérogénéités de la couche de produits de corrosion et couplages galvaniques, 2015.

F. Ropital and Y. Chauvin, Corrosion and degradation of metallic materials: understanding of the phenomena and applications in petroleum and process industries, 2010.

K. J. Rosman and P. D. Taylor, Isotopic compositions of the elements, Pure and Applied Chemistry, vol.70, pp.217-235, 1997.

W. M. Rutherford, Separation of Isotopes in the Thermal Diffusion Column, Separation and Purification Methods, vol.4, pp.305-350, 1975.

M. Saheb, M. Descostes, D. Neff, H. Matthiesen, A. Michelin et al., Iron corrosion in an anoxic soil: Comparison between thermodynamic modelling and ferrous archaeological artefacts characterised along with the local in situ geochemical conditions, Applied geochemistry, vol.25, pp.1937-1948, 2010.

N. O. San, H. Naz?r, and G. Dönmez, Microbially influenced corrosion and inhibition of nickel-zinc and nickel-copper coatings by Pseudomonas aeruginosa, Corrosion Science, vol.79, pp.177-183, 2014.

K. Sauer, A. K. Camper, G. D. Ehrlich, J. W. Costerton, and D. G. Davies, Pseudomonas aeruginosa displays multiple phenotypes during development as a biofilm, Journal of bacteriology, vol.184, pp.1140-1154, 2002.

M. J. Scaini, G. M. Bancroft, J. W. Lorimer, and L. M. Maddox, The interaction of aqueous silver species with sulphur-containing minerals as studied by XPS, AES, SEM, and electrochemistry, Geochimica et Cosmochimica Acta, vol.59, pp.2733-2747, 1995.

E. Schaschl, Elemental sulfur as a corrodent in deaerated neutral aqueous solutions, Brea. Materials Performance, vol.19, p.4, 1980.

E. A. Schauble, Applying Stable Isotope Fractionation Theory to New Systems, Reviews in Mineralogy and Geochemistry, vol.55, pp.65-111, 2004.

M. A. Schoonen and H. L. Barnes, Reactions forming pyrite and marcasite from solution: I. Nucleation of FeS2 below 100°C, Geochimica et Cosmochimica Acta, vol.55, pp.1495-1504, 1991.

J. H. Scofield, Hartree-Slater subshell photoionization cross-sections at 1254 and 1487 eV, Journal of Electron Spectroscopy and Related Phenomena, vol.8, pp.129-137, 1976.

C. Sease, L. S. Selwyn, S. Zubiate, D. F. Bowers, and D. R. Atkins, Problems with coated silver: whisker formation and possible filiform corrosion, Studies in Conservation, vol.42, pp.1-10, 1997.

A. Seyeux and P. Marcus, Analysis of the chemical or bacterial origin of iron sulfides on steel by time of flight secondary ion mass spectrometry (ToF-SIMS), Corrosion Science, vol.112, pp.728-733, 2016.

K. Shimizu, K. Aoki, and R. A. Osteryoung, Electrochemical behavior of sulfide at the silver rotating disc electrode: Part I. Polarization behavior of silver sulfide films, Journal of Electroanalytical Chemistry and Interfacial Electrochemistry, vol.129, pp.159-169, 1981.

D. W. Shoesmith, The Formation of Ferrous Monosulfide Polymorphs during the Corrosion of Iron by Aqueous Hydrogen Sulfide at 21°C, Journal of The Electrochemical Society, vol.127, p.1007, 1980.

M. S. Sim, S. Ono, K. Donovan, S. P. Templer, and T. Bosak, Effect of electron donors on the fractionation of sulfur isotopes by a marine Desulfovibrio sp, Geochimica et Cosmochimica Acta, vol.75, pp.4244-4259, 2011.

S. N. Smith and M. W. Joosten, Corrosion of carbon steel by H2S in CO2 containing oilfield environments, 2006.

T. Stephan, TOF-SIMS in cosmochemistry, Planetary and Space Science, vol.49, pp.859-906, 2001.

H. A. Videla and L. K. Herrera, Understanding microbial inhibition of corrosion. A comprehensive overview, International Biodeterioration & Biodegradation, vol.63, pp.896-900, 2009.

C. Wagner, Investigations on Silver Sulfide, The Journal of Chemical Physics, vol.21, pp.1819-1827, 1953.

J. N. Wanklyn and C. J. Spruit, Influence of sulphate-reducing bacteria on the corrosion potential of iron, Nature, vol.169, p.928, 1952.

C. J. Warde, J. Corish, and C. D. O'briain, Electrochemical Studies at Silver/Alpha-Silver Sulfide Interfaces I. The Sulfidation of Silver, Journal of the Electrochemical Society, vol.122, pp.1421-1426, 1975.

G. W. Warren, B. Drouven, and D. W. Price, Relationships between the pourbaix diagram for Ag-SH 2 O and electrochemical oxidation and reduction of Ag 2 S, Metallurgical Transactions B, vol.15, pp.235-242, 1984.

J. F. Weaver and G. B. Hoflund, Surface Characterization Study of the Thermal Decomposition of AgO, The Journal of Physical Chemistry, vol.98, pp.8519-8524, 1994.

A. J. Wikie?, I. Datsenko, M. Vera, and W. Sand, Impact of Desulfovibrio alaskensis biofilms on corrosion behaviour of carbon steel in marine environment, Bioelectrochemistry, vol.97, pp.52-60, 2014.

A. G. Wikjord, T. E. Rummery, F. E. Doern, and D. G. Owen, Corrosion and deposition during the exposure of carbon steel to hydrogen sulphide-water solutions, Corrosion Science, vol.20, pp.651-671, 1980.

R. T. Wilkin and H. L. Barnes, Pyrite formation by reactions of iron monosulfides with dissolved inorganic and organic sulfur species, Geochimica et Cosmochimica Acta, vol.60, pp.4167-4179, 1996.

C. R. Woese, Whither microbiology Phylogenetic trees, Current biology: CB, vol.6, pp.1060-1063, 1996.

J. D. Wright, Global climate change in marine stable isotope records, AGU Reference Shelf, pp.427-433, 2000.

S. Yamaguchi and T. Katsurai, Zur Bildung des ferromagnetischen Fe 3 S 4, Colloid & Polymer Science, vol.170, pp.147-148, 1960.

S. Yamaguchi and H. Wada, Aging of colloidal iron sulfide, Journal of Colloid and Interface Science, vol.40, pp.477-478, 1972.

C. J. Yang, C. H. Liang, and X. Liu, Tarnishing of silver in environments with sulphur contamination, Anti-Corrosion Methods and Materials, vol.54, pp.21-26, 2007.

S. Yang, J. Wu, and A. Christou, Initial stage of silver electrochemical migration degradation, Microelectronics Reliability, vol.46, pp.1915-1921, 2006.

K. Zhao, Investigation of microbiologically influenced corrosion (MIC) and biocide treatment in anaerobic salt water and development of a mechanistic MIC model, 2008.

V. Zinkevich and I. B. Beech, Isolation of intact high molecular weight chromosomal DNA from Desulfovibrio spp, Mol. Biol. Today, vol.1, pp.29-33, 2000.

V. Zinkevich and I. B. Beech, Screening of sulfate-reducing bacteria in colonoscopy samples from healthy and colitic human gut mucosa, FEMS Microbiol. Ecol, vol.34, pp.147-155, 2000.

D. Tableau, Compositions chimiques et propriétés physico-chimiques du milieu dans lequel l'échantillon d'acier N80 a été exposé pendant 4 mois