International audience<br/>Neutron irradiation affects the mechanical properties of Reactor Pressure Vessel (RPV) steels used in Light Water Reactors (LWR). Fracture properties are particularly monitored based on surveillance programs, mostly through Charpyimpact tests. The evolutions of Ductile Brittle Transition Temperature (DBTT) and Upper Shelf Energy (USE) with irradiation are evaluated and used for structural integrity assessment depending on regulation procedures. Semi-empiricalcorrelations have been proposed to predict DBTT and USE shifts as a function of material chemical composition and fastneutron fluence, based on extended experimental database. In this study, numerical simulations of Charpy impact tests areperformed in order to predict quantitatively the evolution of USE with irradiation. In a first part, the mechanical propertiesof an A508 Cl3 RPV steel are presented, including tensile tests on flat and notched samples and Charpy impact tests, forvarious irradiation levels and test temperatures. USE values are found to be within the bounds of correlation curves. In asecond part, the experimental data are used to calibrate constitutive equations describing the material behavior up to highstrain levels. Charpy impact test finite element simulations are then detailed, including ductile fracture modelling. In athird part, the ductile fracture model is calibrated based on the experimental data, and numerical simulations are used topredict the evolution of USE with irradiation. The decrease of USE with irradiation is recovered, and the numerical results are found to be in quantitative agreement with the correlation curves. Additional simulations confirm the agreementfor different reference unirradiated USE and chemical composition, as well as using a simplified ductile fracture model.These results indicate that numerical simulations of Charpy impact test relying on calibrated constitutive equations can beused to predict USE and required experimental characterization are finally discussed.<br/>

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