Y. Kato, T. Nitawaki, and Y. Muto, Medium temperature carbon dioxide gas turbine reactor, Nuclear Engineering and Design, vol.230, issue.1-3, pp.195-207, 2004.
DOI : 10.1016/j.nucengdes.2003.12.002

J. Floyd, N. Alpy, D. Haubensack, G. Avakian, and G. Rodriguez, On-Design Efficiency Reference Charts for the Supercritical CO2 Brayton Cycle coupled to an SFR, Proceedings of ICAPP 11054, 2011.

F. Rouillard, G. Moine, M. Tabarant, and R. C. Ruiz, Corrosion of 9Cr Steel in CO 2 at intermediate Temperature II: Mechanism of Carburization, Oxidation of Metals, pp.77-57, 2011.

T. Furukawa, Y. Inagaki, and M. Aritomi, Corrosion Behavior of FBR Structural Materials in High Temperature Supercritical Carbon Dioxide, Journal of Power and Energy Systems, vol.4, issue.1, pp.252-261, 2010.
DOI : 10.1299/jpes.4.252

G. H. Meier, K. Jung, N. Mu, N. M. Yanar, F. S. Pettit et al., Effect of Alloy Composition and Exposure Conditions on the Selective Oxidation Behavior of Ferritic Fe???Cr and Fe???Cr???X Alloys, Oxidation of Metals, vol.50, issue.5-6, pp.74-319, 2010.
DOI : 10.1007/s11085-010-9215-5

D. R. Holmes, D. Mortimer, and J. Newell, Discovery and assessment of accelerated corrosion in Fe -9Cr alloys and steels, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.151-163, 1974.

R. Darras, D. Leclerq, and H. Loriers, Compatibilité des aciers de structure avec le gaz carbonique sous pression aux températures moyennes, Corrosion of Reactor Materials), vol.409, issue.2, 1962.

F. Rouillard, Report on the corrosion behaviour of a 9Cr Ferritic/Martensitic steel and several 18-22Cr austenitic steels in CO2 at 550°C -Comparison between exposure at 1 bar and 250 bars, 2009.

P. L. Harrison, R. B. Dooley, S. K. Lister, D. B. Meadowcroft, P. J. Nolan et al., The Oxidation of 9Cr-1Mo Steels in Carbon Dioxide: a Discussion of Possible Mechanisms, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.220-233, 1974.

M. R. Taylor, J. M. Clavert, and K. A. Hay, Tracer Movement in Growing Oxide Scale on an Fe -8,5 wt%Cr Binaru Alloy, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.272-283, 1974.

F. Rouillard, L. Martinelli, and J. C. Ruiz, Corrosion of 9Cr Steel in CO2 at Intermediate Temperature I: Mechanism of Void-Induced Duplex Oxide Formation, Oxidation of Metals, vol.90, issue.292, pp.77-104, 2011.
DOI : 10.1007/s11085-011-9271-5

L. Martinelli, Oxidation mechanism of a Fe???9Cr???1Mo steel by liquid Pb???Bi eutectic alloy (Part I), Corrosion Science, vol.50, issue.9, p.2523, 2008.
DOI : 10.1016/j.corsci.2008.06.050

J. Robertson and M. I. Manning, Criteria for formation of single layer, duplex, and breakaway scales on steels, Materials Science and Technology, vol.25, issue.12, p.1064, 1988.
DOI : 10.1007/BF00603534

G. B. Gibbs, R. E. Pendlebury, and M. R. Wooton, Protective and Breakaway Corrosion of Mild Steel in CO2, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.59-72, 1974.

P. L. Surman and A. M. Brown, The Role of Carbon in the Breakaway Oxidation of Mild Steel in High Pressure Carbone Dioxide, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.85-96, 1974.

M. G. Cox, B. Mc-enaney, and V. D. Scott, Structure and Growth of Oxide on Iron-Chromium Alloys, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.20-247, 1974.

M. G. Cox, B. Mcenaney, and V. D. Scott, Vacancy condensation and void formation in duplex oxide scales on alloys, Philosophical Magazine, vol.196, issue.2, p.309, 1973.
DOI : 10.1080/14786437308217455

W. J. Quadakkers, T. Olszewski, J. Piron-abellan, and L. Singheiser, Oxidation of metallic materials in simulated CO2/H2O-rich service environments relevant to an oxyfuel plant, VDI-Berichte 2102, pp.81-103, 2012.

A. M. Huntz, V. Bague, G. Beauple-',, C. Hauta, C. Se´ve´rac et al., Effect of silicon on the oxidation resistance of 9% Cr steels, Applied Surface Science, vol.207, issue.1-4, p.207, 2003.
DOI : 10.1016/S0169-4332(02)01505-2

J. Pirón-abellán, T. Olszewski, G. H. Meier, L. Singheiser, and W. J. Quadakkers, The oxidation behaviour of the 9% Cr steel P92 in CO2-and H2O-rich gases relevant to oxyfuel environments, International Journal of Materials Research, pp.101-287, 2010.

C. Anghel, E. Hörnlund, G. Hultquist, and M. Limbäck, Gas phase analysis of CO interactions with solid surfaces at high temperatures, Applied Surface Science, vol.233, issue.1-4, pp.392-401, 2004.
DOI : 10.1016/j.apsusc.2004.04.001

Q. Lu, G. Hultquist, and T. Akermark, In situ SIMS Analysis of the initial oxidation of a commercial FeCrAl alloy in H2O-O2 gas at 600-850K, 12th Scandinavian Corrosion Congress& Eurocorr, p.92, 1992.

B. Ahmad and P. Fox, The effect of surface contamination on the transient oxidation of Ni-20Cr, Materials at High Temperatures, vol.17, pp.265-270

E. Park and M. Spiegel, Effects of heat treatments on near surface elemental profiles of Fe???15Cr polycrystalline alloy, Corrosion Engineering, Science and Technology, vol.239, issue.3, pp.40-217, 2005.
DOI : 10.1080/14786441208561131

H. Cheng, Role of transition metal oxides in metal dusting: Density functional study, AIChE Journal, vol.91, issue.300, pp.188-196, 1998.
DOI : 10.1002/aic.690440120

K. Honkala and K. Laasonen, Oxygen Molecule Dissociation on the Al(111) Surface, Physical Review Letters, vol.84, issue.4, pp.705-708, 2000.
DOI : 10.1103/PhysRevLett.84.705

D. C. Sorescu, First-principle calculations of the adsorption, dissusion and dissociation of CO molécule on the Fe (1 0 0) surface, Phys. Rev, p.66, 2002.

C. Anghel and Q. Dong, A gas phase analysis technique applied to in -situ studies of gas?solid interactions, Journal of Materials Science, pp.42-3440, 2007.

H. Akermark and G. , Probabilities for oxygen exchange in O2 in contact with a solid surface, J. Trace and Microprobe Techniques, vol.14, issue.2, pp.377-388, 1996.

E. Hörnlund, Studies of Dissociation of Diatomic Molecules with Isotope Spectroscopy, ChemInform, vol.199, issue.13, pp.195-210, 2002.
DOI : 10.1002/chin.200313210

C. Anghel, G. L. Hultquist, and M. , Influence of Pt, Fe/Ni/Cr-containing intermetallics and deuterium on the oxidation of Zr-based materials, Journal of Nuclear Materials, vol.340, issue.2-3, p.271, 2005.
DOI : 10.1016/j.jnucmat.2004.12.005

Z. Tökei, H. Viefhaus, and H. J. Grabke, Initial stages of oxidation of a 9CrMoV-steel: role of segregation and martensite laths, Applied Surface Science, vol.165, issue.1, pp.165-188, 2000.
DOI : 10.1016/S0169-4332(00)00285-3

C. Leygraf and G. Hultquist, Initial oxidation stages on Fe???Cr(100) and Fe???Cr(110) surfaces, Surface Science, vol.61, issue.1, pp.61-69, 1976.
DOI : 10.1016/0039-6028(76)90408-8

L. Greeff and S. , The oxidation of industrial FeCrMo steel, Corrosion Science, vol.42, issue.10, pp.1725-1740, 2000.
DOI : 10.1016/S0010-938X(00)00026-3

G. Hultquist and C. Leygraf, The initiation of selective oxidation of a ferritic stainless steel at low temperatures and oxygen pressures, Corrosion Science, vol.22, issue.4, pp.331-346, 1982.
DOI : 10.1016/0010-938X(82)90034-8

M. G. Cox, B. Mcenaney, and V. D. Scott, Structure and growth of oxide on iron-chromium alloys, British Nuclear Energy Society International Conferance on corrosion of steels in CO2, pp.247-255, 1974.

A. Dhooge, S. Huysmans, B. Vandenberghe, J. Vekeman, and C. Jochum, New 12% Cr-steel for tubes and pipes in power plants with steam temperatures up to 650??C, Materials at High Temperatures, vol.23, issue.3-4, pp.155-164, 2006.
DOI : 10.1179/mht.2006.009

F. Rouillard, L. Martinelli, and J. C. Ruiz, Corrosion of 9Cr Steel in CO2 at Intermediate Temperature I: Mechanism of Void-Induced Duplex Oxide Formation, Oxidation of Metals, vol.90, issue.292, pp.77-104, 2011.
DOI : 10.1007/s11085-011-9271-5

T. M. Duc, Analyse de surface par ESCA -Principe et instrumentation, Techniques de l'ingénieur, pp.2625-2626

L. Martinelli, Mecanisme de corrosion de l'acier T91 par l'eutectique Pb-Bi utilisé comme materiau de cible de spallation. Importance pour les réacteurs hybrides, Thèse Université Paris VI, 2005.

A. C. Sabioni, A. M. Huntz, L. C. Borges, and F. Jomard, polycrystals and thin films by SIMS, Philosophical Magazine, vol.5, issue.12, pp.1921-1937, 2007.
DOI : 10.1080/14786430601120462
URL : https://hal.archives-ouvertes.fr/hal-00192388

L. Martinelli, Oxidation mechanism of an Fe???9Cr???1Mo steel by liquid Pb???Bi eutectic alloy at 470??C (Part II), Corrosion Science, vol.50, issue.9, pp.2537-2548, 2008.
DOI : 10.1016/j.corsci.2008.06.051

J. Töpfer, S. Aggarwal, and R. Dieckmann, Point defects and cation tracer diffusion in (CrxFe1 ??? x)3 ??? ??O4 spinels, Solid State Ionics, vol.81, issue.3-4, pp.251-266, 1995.
DOI : 10.1016/0167-2738(95)00190-H

O. Atkinson and T. Dwyer, 55Fe diffusion in magnetite crystals at 500??? C and its relevance to oxidation of iron, Journal of Materials Science, vol.15, issue.8, pp.2371-2379, 1983.
DOI : 10.1007/BF00541841

L. Martinelli and F. Balbaud-célérier, Modelling of the oxide scale formation on Fe-Cr steel during exposure in liquid lead-bismuth eutectic in the 450-600?????C temperature range, Materials and Corrosion, vol.461, issue.464, pp.531-542, 2011.
DOI : 10.1002/maco.201005871

J. Chivot, Thermodynamique des produits de corrosion, Collection Sciences & Techniques, 2004.

L. Martinelli, E. Hassan, N. K. Guillot, and C. Desgranges, Oxidation mechanism of Fe -9Cr steel: Comparison between steem/hydrogen environments and liquid lead bismuth alloy

M. Robbins, Magnetic properties and site distributions in the system FeCr2O4-Fe3O4, J. Phys. Chem, 1971.
URL : https://hal.archives-ouvertes.fr/jpa-00214515

A. C. Sabioni, A. M. Huntz, F. Silva, and F. Jomard, Diffusion of iron in Cr2O3: polycrystals and thin films, Materials Science and Engineering: A, vol.392, issue.1-2, pp.392-254, 2005.
DOI : 10.1016/j.msea.2004.09.033
URL : https://hal.archives-ouvertes.fr/hal-00265460

M. Es-souni and A. Mosser, AES study of the effect of segregated sulfur on the oxidation of an Fe - at6%Si alloy surface, Applied Surface Science, pp.35-219, 1988.

J. F. O-'hanlon, A user's Guide to Vacuum Technology

D. Young, High Temperature Oxidation and Corrosion of Metals, pp.68-71, 2008.

J. Philibert, Diffusion et transport de matière dans les solides, 1990.

Z. Tökei, K. Hennesen, H. Viefhaus, and H. J. Grabke, Diffusion of chromium in ferritic and austenitic 9???20 wt-%chromium steels, Materials Science and Technology, vol.66, issue.4, p.16, 2000.
DOI : 10.1016/1359-6462(96)00148-0

T. M. Duc, Analyse de surface par ESCA -Principe et instrumentation, pp.1-31

S. Tanuma, C. J. Powell, and D. R. Penn, Calculations of electron inelastic mean free paths. V. Data for 14 organic compounds over the 50-2000 eV range, Surface and Interface Analysis, vol.20, issue.3, p.165, 1993.
DOI : 10.1002/sia.740210302

R. W. Paynter, Modification of the Beer-Lambert equation for application to concentration gradients, Surface and Interface Analysis, vol.22, issue.4, p.4, 1981.
DOI : 10.1002/sia.740030410

P. J. Cumpson, Angle-resolved XPS depth-profiling strategies, Applied Surface Science, vol.144, issue.145, pp.16-20, 1999.
DOI : 10.1016/S0169-4332(98)00752-1

V. B. Glasko, Inverse Problems of Mathematical Physics, 1988.