G. Bernhart, G. Moulinier, O. Brucelle, and D. Delagnes, High temperature low cycle fatigue behaviour of a martensitic forging tool steel, Int J Fatigue, vol.21, issue.2, pp.179-86, 1999.
URL : https://hal.archives-ouvertes.fr/hal-01701678

C. Bournicon, Traitement Thermique, vol.246, pp.70-77, 1991.

D. Delagnes, Isothermal fatigue behaviour and lifetime of a 5Cr hot work tool steel around the LCF-HCF transition

R. Komanduri and Z. B. Hou, Int J Mech Sci, vol.43, issue.1, pp.57-88, 2001.

C. L. Gibbons, J. I. Dunn, and . Heat, , pp.6-9, 1980.

Z. Zhang, D. Delagnes, and G. Bernhart, Stress-strain behaviour of tool steels under thermo-mechanical loadings: experiments and modelling, Proceedings of the 5th international tooling conference, pp.205-218, 1999.

V. Velay, G. Bernhart, Z. Zhang, and L. Penazzi, Cyclic behaviour CAMP2002, high-temperature fatigue, pp.3-4

G. Bernhart, B. G. Choi, Z. Zhang, and D. Delagnes, Single specimen methodology for elasto-visco-plastic fatigue model identification of martensitic steels, Euromat, pp.1077-82, 2000.

Z. Zhang, D. Delagnes, and G. Bernhart, Anisothermal cyclic plasticity modelling of martensitic steels, Int J Fatigue, vol.24, issue.6, pp.635-683, 2002.
URL : https://hal.archives-ouvertes.fr/hal-01715087

Z. Zhang, D. Delagnes, and G. Bernhart, Microstructure evolution of hot-work tool steels during tempering and definition of a kinetic law based on hardness measurements, Mater Sci Eng A, vol.380, issue.1-2, pp.222-252, 2004.
URL : https://hal.archives-ouvertes.fr/hal-01715086

Z. Zhang, Anisothermal cyclic behaviour modelling with taking account of tempering effect of a martensitic tool steel 55NiCrMoV7

Z. Zhang, D. Delagnes, and G. Bernhart, Tempering effect on cyclic behaviour of a martensitic tool steel, Proceedings of the 6th international tooling conference: the use of tool steels: experience and research, pp.573-89
URL : https://hal.archives-ouvertes.fr/hal-01788444

M. Mutoh and Y. Okazaki, Low cycle fatigue strength and its prediction for dissimilar-metal electron-beam-welded joints at high temperature, High temperature creep-fatigue, pp.183-202, 1988.

H. Okamura, R. Ohtani, and K. Saito, Nucl Eng Des, vol.193, issue.3, pp.243-54, 1999.

D. Ye, X. Tong, L. Yao, and . Mater, Chem Phys, issue.56, pp.199-204, 1998.

X. Chen and S. Zhao, Evaluation of fatigue damage at welded tube joint under cyclic pressure using surface hardness measurement, Eng Fail Anal, vol.12, pp.616-638, 2005.

N. Mebarki, P. Lamesle, F. Delmas, D. Delagnes, and C. Levaillant, Relationship between microstructure and mechanical properties of a 5Cr hot-work tool steel, Proceedings of the 6th international tooling conference: the use of tool steels: experience and research, pp.617-649
URL : https://hal.archives-ouvertes.fr/hal-01788442

N. Mebarki, Relationship between microstructure and mechanical properties of tempered martensitic steels

J. Lemaitre and J. L. Chaboche, Mechanics of solids, 1990.

D. Francois, A. Pineau, and A. Zaoui, Comportement mécanique des matériaux-viscoplasticité, endommagement, mécanique de la rupture, 1993.

J. Pesicka, R. Kuzel, A. Dronhofer, and G. Eggeler, The evolution of dislocation density during heat treatment and creep of tempered martensite ferritic steels, Acta Mater, vol.51, issue.16, pp.4847-62, 2003.

J. Pesicka, A. Dronhofer, and G. Eggeler, Free dislocations and boundary dislocations in tempered martensite ferritic steels, Mater Sci Eng A, issue.1-2, pp.176-80, 2004.

D. Delagnes, P. Lamesle, M. H. Mathon, N. Mebarki, and C. Levaillant, Influence of silicon content on the precipitation of secondary carbides and fatigue properties of a 5%Cr tempered martensitic steel, Mater Sci Eng A, vol.394, issue.1-2, pp.435-479, 2005.
URL : https://hal.archives-ouvertes.fr/hal-01715084

N. Mebarki, D. Delagnes, P. Lamesle, F. Delmas, and C. Levaillant, Relationship between microstructure and mechanical properties of a 5%Cr tempered martensitic tool steel, Mater Sci Eng A, issue.1-2, pp.171-176, 2004.
URL : https://hal.archives-ouvertes.fr/hal-01715085

Z. Hu and J. Xiao, Cyclic softening characteristics and mechanism of hot work die steels during low cycle fatigue, Fatigue '90, Proceedings of the 4th international conference on fatigue and fatigue thresholds, pp.469-74, 1990.

K. Kanazawa, K. Yamaguchi, and K. Kobayashi, The temperature dependence of low cycle fatigue behaviour of martensitic stainless steels, Mater Sci Eng, vol.40, pp.89-96, 1979.

J. B. Vogt, G. Degallaix, and J. Foct, Cyclic mechanical behaviour and microstructure of a 12Cr-Mo-V martensitic stainless steel, Fatigue Fract Eng Mater Struct, vol.11, pp.435-481, 1988.

J. B. Vogt, S. Argillier, J. Leon, J. P. Massoud, and V. Prunier, Mechanisms of cyclic plasticity of a ferrite-bainite 21/4Cr1Mo steel after long-term service at high temperature, ISIJ Int, vol.39, pp.1198-203, 1999.

H. Chai and Q. Fan, fatigue softening mechanism of low carbon tempered martensite, Fatigue '93, Proceedings of the 5th international conference on fatigue and fatigue thresholds, pp.195-200, 1993.

G. Eggeler, The effect of long-term creep on particle coarsening in tempered martensite ferritic steels, Acta Metall, vol.37, issue.12, pp.3225-3259, 1989.

H. J. Chang, C. H. Tsai, and J. J. Kai, Effects of temperature on the cyclic deformation behaviour and microstructural changes of 12Cr1MoVW martensitic stainless steel, Int J Pres Ves Pip, vol.59, issue.1-3, pp.31-40, 1994.

Z. G. Wang, K. Rahka, P. Nenonen, and C. Laird, Changes in morphology and composition of carbides during cyclic deformation at room and elevated temperature and their effect on mechanical properties of CrMo-V steel, Acta Metall, vol.33, pp.2129-2170, 1985.