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On non stress-free junctions between martensitic plates. (English) Zbl 1458.74115

Summary: The analytical understanding of microstructures arising in martensitic phase transitions relies usually on the study of stress-free interfaces between different variants of martensite. However, in the literature there are experimental observations of non stress-free junctions between martensitic plates, where the compatibility theory fails to be predictive. In this work, we focus on \(V_{II}\) junctions, which are non stress-free interfaces between different martensitic variants experimentally observed in \(\mathrm{Ti}_{74}\mathrm{Nb}_{23}\mathrm{Al}_3\). We first motivate the formation of some non stress-free junctions by studying the two well problem under suitable boundary conditions. We then give a mathematical characterisation of \(V_{II}\) junctions within the theory of elasto-plasticity, and show that for deformation gradients as in \(\mathrm{Ti}_{74}\mathrm{Nb}_{23}\mathrm{Al}_3\) our characterisation agrees with experimental results. Furthermore, we are able to prove that, under suitable hypotheses that are verified in the study of \(\mathrm{Ti}_{74}\mathrm{Nb}_{23}\mathrm{Al}_3, V_{II}\) junctions are strict weak local minimisers of a simplified energy functional for martensitic transformations in the context of elasto-plasticity.

MSC:

74N05 Crystals in solids
74K30 Junctions
74K20 Plates
74G65 Energy minimization in equilibrium problems in solid mechanics
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