论文信息 - Kinetics of materials with wiggly energies: Theory and application to the evolution of twinning microstructures in a Cu-Al-Ni shape memory alloy

Kinetics of materials with wiggly energies: Theory and application to the evolution of twinning microstructures in a Cu-Al-Ni shape memory alloy

We analyse the kinetics of the transition between two variants of martensite during biaxial dead loading. The volume fraction of one martensite variant versus the applied loads exhibits an unusual hysteresis, characterized by a sensitive dependence on the amplitude of the loads and a dissipationless response at small amplitude. Observation of the microscopic volume fraction at the level of a few bands of martensite reveals that the main mechanism by which one variant grows at the expense of another is a tip-splitting event; the tips of martensite needles present in the specimen suddenly split. This leads us to adopt a form of the energy in which many little wiggles are superposed on a slowly varying function that accounts for the loading device, elastic and interfacial energies. We analyse the resulting microscopic kinetic law by deriving from it a macroscopic kinetic equation that governs the average response. This law inherits the phenomenon of 'getting stuck in local minima of the energy'. It leads to good qualitative (and fair quantitative) agreement with observation over a very wide range of different kinds of experiment.

[1] P. Hartman. Ordinary Differential Equations , 1965 .

[2] T. Hou,et al. Homogenization of linear transport equations with oscillatory vector fields , 1992 .

[3] J. Ball,et al. Fine phase mixtures as minimizers of energy , 1987 .

[4] K. Shimizu,et al. Morphology and Crystallography of Thermoelastic γ' Cu-Al-Ni Martensite , 1969 .

[5] S. Kojima,et al. Measurement of elastic constants , 1983 .

[6] François Murat,et al. Remarques sur l'homogénéisation de certains problèmes quasi-linéaires , 1982 .

[7] Kaushik Bhattacharya,et al. Wedge-like microstructure in martensites , 1991 .

[8] R. Abeyaratne,et al. On the effect of the heat generated during a stress-induced thermoelastic phase transformation , 1995 .

[9] Perry H Leo,et al. Transient heat transfer effects on the pseudoelastic behavior of shape-memory wires , 1993 .

[10] R. Kohn,et al. Branching of twins near an austenite—twinned-martensite interface , 1992 .

[11] T. Shield. Orientation dependence of the pseudoelastic behavior of single crystals of CuAlNi in tension , 1995 .

[12] Vives,et al. Distributions of avalanches in martensitic transformations. , 1994, Physical review letters.