Benoît Panicaud scite author profile

Owing to its selectivity, diffraction is a powerful tool for analysing the mechanical behaviour of polycrystalline materials at the mesoscale (phase and/ or grain scale). In situ neutron diffraction during tensile tests and elastoplastic self-consistent modelling were used to study slip phenomena occurring on crystallographic planes at small and large deformation. The critical resolved shear stresses in both phases of duplex stainless steel were found for samples subjected to different thermal treatments. The evolution of grain loading was also determined by showing the large differences between stress concentration for grains in ferritic and austenitic phases. It was found that, for small loads applied to the sample, linear elastic deformation occurs in both phases. When the load increases, austenite starts to deform plastically, while ferrite remains in the elastic range. Finally, both phases undergo plastic deformation until sample fracture. By using an original calibration of diffraction data, the range of the study was extended to large sample deformation. As a result, mechanical effects that can be attributed to damage processes initiated in ferrite were observed. research papers J. Appl. Cryst. (2011). 44, 966-982 A. Baczmanski et al. Aged duplex stainless steel under deformation 967 research papers J. Appl. Cryst. (2011). 44, 966-982 A. Baczmanski et al. Aged duplex stainless steel under deformation 977 Figure 11Elastic lattice strains (h" TD i fhklg ) perpendicular to the loading direction (RD) versus the applied true stress AE RD for aged UR45N samples deformed in the tensile test. research papers J. Appl. Cryst. (2011). 44, 966-982 A. Baczmanski et al. Aged duplex stainless steel under deformation 981

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Elastoplastic deformation and damage process in duplex stainless steels studied using synchrotron and neutron diffractions in comparison with a self-consistent model

Baczmański

Zhao

Gadalińska

et al. 2016

International Journal of Plasticity

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In situ time of flight neutron diffraction and X-ray synchrotron diffraction methods were applied to measure lattice strains in duplex steels during a tensile test. The experimental results were used to study slips on crystallographic planes and the mechanical effects of damage occurring during plastic deformation. For this purpose the prediction of an elastoplastic self-consistent model was compared with the experimental data. The used methodology allowed to determine the elastic limits and parameters describing work hardening in both phases of studied polycrystalline materials. In the second part of this work the developed elastoplastic model was applied to study damage occurring in the ferritic phase. The theoretical results showed a significant reduction of stresses localized in the damaged phase (ferrite) and confirmed the evolution of the lattice strains measured in the ferritic and austenitic phases.

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Benoît Panicaud

Neutron time-of-flight diffraction used to study aged duplex stainless steel at small and large deformation until sample fracture

Elastoplastic deformation and damage process in duplex stainless steels studied using synchrotron and neutron diffractions in comparison with a self-consistent model

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