6. Bibliography#

  1. Le Corre, V.: Study of the ductile tear/brittle fracture competition: Application to the mechanical strength of C-Mn steel tubes and their welded joints. Thesis from the Ecole Centrale de Lille, 2006.

  1. Andrieu, A.: Mechanisms and multi-scale modeling of trans-and inter-granular brittle fracture of steels for Pressurized Water Reactors, in connection with thermal aging. Doctoral thesis from the École Nationale Supérieure des Mines de Paris, 2013.

  1. Renevey, S.: Global and local approaches to failure in the fragile-ductile transition domain of low-alloy steel. Thesis of CEA, Saclay, 1998.

  1. Marais, A.: Influence of static aging on the ductile-brittle transition of C-Mn steels. Doctoral thesis from the École Nationale Supérieure des Mines de Paris, 2012.

  2. Graff, S.: Viscoplastic behavior of zirconium alloys in the temperature range 20°C—400°C: characterization and modeling of strain ageing phenomena. Doctoral thesis from the École Nationale Supérieure des Mines de Paris, 2006.

  3. Belotteau, J.: Behaviour and fracture of C-Mn steel in the presence of aging under deformation. Doctoral thesis from École Centrale Paris, 2009.

  1. Wang, H.: Mechanical behavior and fracture of C-Mn steels in the presence of dynamic aging under deformation. Doctoral thesis from École Centrale Paris, 2011.

  1. Mathieu, J-P.: Micromechanical analysis and modeling of the behavior and brittle fracture of steel 16 MND5: taking into account microstructural heterogeneities. Doctoral thesis from ENSAM, 2007.

  1. Thompson, A.W., Knott J.F.: Micromechanisms of brittle fracture. Metallurgical Transactions A, 24 (3) :523—534, 1993.

  1. Griffith, A.: The phenomena of rupture and flow in solids. Philosophical Transactions of the Royal Society of London, vol. 221, pp. 163—198, 1921.

  1. François, D., Pineau, A., A., Zaoui, A.: Mechanical behavior of materials. Hermès, Paris, pp.139-141, 1993.

  1. McMahon, C., Cohen, M.: Initiation of cleavage in polycrystalline iron. Acta Metallurgica, vol. 13, no. 6, pp. 591—604, 1965.

  2. Bouchet, C., Tanguy, B., Besson, J., Besson, J., J., Bugat, S.: Prediction of the effects of neutron irradiation on the charpy ductile to brittle transition curve of an A508 pressure vessel steel. Computational materials science, vol. 32, no. 3, pp. 294-300, 2005.

  1. Pineau, A., Tanguy, B.: Advances in cleavage fracture modelling in steels: Micromechanical, numerical and multiscale aspects, in Physical Reports, Academy of Sciences, 2010.

  2. Kroon, M., Faleskog, J.: Micromechanics of cleavage fracture initiation in ferritic steels by carbide cracking. Mr Mech. Phys. Solids, vol. 53, pp 171—196, 2005.

  3. Bordet, S.R., Karstensen, A.D., Knowles, A.D., Knowles, D.M., Wiesner, C.S.: « A new statistical local criterion for cleavage fracture in steel. Part I: model presentation », Eng. Frac. Mech., Vol. 72, pp.435-452, 2005.

  4. Odette, G.R., Yamamoto, T., T., Rathburn, H.J.: Cleavage fracture and irradiation embrittlement of fusion reactor alloys: mechanisms, multiscale models, toughness measurements, and implications for structural integrity assessment. J. of Nucl. Mat., vol. 323, pp 313—340, 2003.

  5. Ritchie, R.O., Knott, J.F. and Rice, J.R.: On the relationship between critical tensile stress and fracture toughness in mild steel. Journal of the Mechanics and Physics of Solids, 21 (6) :395—410, 1973.

  6. Curry, D.A. and Knott, J.F.: The relationship between fracture toughness and microstructure in the cleavage fracture of mild steel. Metal Science, 10 (1) :1—6, 1976.

  7. Beremin, F.: « A local criterion for cleavage fracture of a nuclear pressure vessel steel », Metall. Trans. 14A, pp 2277-2287, 1981.

  8. Wallin, K., Saario, T., Torronen, K.: Statistical model for carbide induced brittle fracture in steel”, Metal Science, 18, 1, pp 13-16, 1984.

  9. Weibull, W.: A statistical theory of the strength of materials. Proc. Roy. Swedish Int Eng. Res., 151:1—53, 1939.

  1. Weibull, W.: A statistical distribution function of wide applicability. Journal of Applied Mechanics, 18:293—297, 1951.

  1. Masson, R. et al.: « Definition of the local approach (in fragile) in the case of any loading path », Note EDF HT-26/00/021.

  1. Tanguy, B.: Modeling the Charpy test using the local approach to rupture. Application to the case of 16 MND5 steel in the transition domain. Doctoral thesis from the École des Mines de Paris, 2001.

  1. Lefevre, W., Masson, R., R., Barbier, R.: « Numerical simulations using the improved Beremin model of hot preloading tests carried out with 18 MND5 steel ». Note EDF HT-26/00/028.

  1. Lefevre, W., Barbier, G., G., Masson, R., R., R., Rousselier, G.: A modified Beremin model to simulate the warm pre-stress effect, » Nuclear Engineering and Design, vol. 216, no. 1—3, no. 1—3, pp. 27-42, 2002.

  2. Tanguy, B., Bouchet, C., Bordet, S.R., S.R., Besson, J., Besson, J., Pineau, A.: « Toward a better understanding of the cleavage in RPV steels: Local mechanical conditions and evaluation of a nucleation enriched Weibull model and of the Beremin model over a large temperature range », 9th European Mechanics of Materials Conference, Local approach to fracture, pp 129-134, Moret sur Loing, 2006.

  1. Wadier, Y., Link between global and local approaches in the mechanics of elastoplastic rupture. Technical note H-T64-2007-00213-FR, EDF R&D, 2007.