Stochastic multiscale modeling of the thermomechanical behavior of polycrystalline shape memory alloys

Abstract: A multi-scale model simulating hysteretic thermomechanical behavior of polycrystalline shape memory alloys (SMA) is presented. Using a kinetic Monte-Carlo approach, the energybased model estimates the stochastic average in terms of volume fraction for a phase or phase variant deriving from the Gibbs free energy density as a selection inside a given population. Indeed pseudo-elastic behavior for example is well-known to be associated with the nucleation of martensite plates inside the austenite parent phase. As… Show more

“…5, a series of raw spectra D(2, y) are obtained, each of which is composed of the three phases of NiTinol: A, M and R. For the proper identification of these phases, it is possible to prepare the specimen to obtain pure A and M phases with either a load-free state at high temperature (austenite) or under load after a full transformation (martensite), with a representative anisotropy along the tensile axis due to the selection of variants. However, this is not the case for the R phase: in a previous study (Chang et al, 2020), by conducting differential scanning calorimetry (DSC) over the NiTinol specimen, it was shown that the R phase is present only in the intermediate stages and never uniformly.…”

“…5(a) at 2 = 49 and 92 correspond to A{110} and A{211}, respectively, which are consistent with the theoretical XRD diffractograms. The {200} peak is not visible in the experimental spectra because of the pronounced crystallographic texture of this laminated material (Chang et al, 2020). Therefore, at this stage, the collected experimental diffraction spectra are taken as the data profile for pure austenite.…”

Three-phase material mapping with incomplete X-ray diffraction spectral information

“…5, a series of raw spectra D(2, y) are obtained, each of which is composed of the three phases of NiTinol: A, M and R. For the proper identification of these phases, it is possible to prepare the specimen to obtain pure A and M phases with either a load-free state at high temperature (austenite) or under load after a full transformation (martensite), with a representative anisotropy along the tensile axis due to the selection of variants. However, this is not the case for the R phase: in a previous study (Chang et al, 2020), by conducting differential scanning calorimetry (DSC) over the NiTinol specimen, it was shown that the R phase is present only in the intermediate stages and never uniformly.…”

“…5(a) at 2 = 49 and 92 correspond to A{110} and A{211}, respectively, which are consistent with the theoretical XRD diffractograms. The {200} peak is not visible in the experimental spectra because of the pronounced crystallographic texture of this laminated material (Chang et al, 2020). Therefore, at this stage, the collected experimental diffraction spectra are taken as the data profile for pure austenite.…”

Three-phase material mapping with incomplete X-ray diffraction spectral information

“…This calculation is complemented by a minimization process of g α regarding the direction cosines of domain families α to take the so-called magnetization rotation mechanism into account. Following this strategy, a Boltzmann function gives the solution of the stochastic approach [13] (with V 0 a reference microscopic volume, k B the Boltzmann constant (1.38 × 10 −23 J.K −1 ) and T the temperature (293 K)).…”

Piezomagnetic behavior: experimental observations and multiscale modeling

Passive piezomagnetic monitoring of structures subjected to in-service cyclic loading: Application to the detection of fatigue crack initiation and propagation