The role of phase interface energy in martensitic transformations: a lattice Monte-Carlo simulation

  title={The role of phase interface energy in martensitic transformations: a lattice Monte-Carlo simulation},
  author={Vladislav A. Yastrebov and Michael Fischlschweiger and Georges Cailletaud and Thomas Antretter},
  journal={Mechanics Research Communications},

Figures from this paper

Embedded NiTi Wires for Improved Dynamic Thermomechanical Performance of Silicone Elastomers
A comprehensive dynamic thermomechanical analysis is performed and the temperature- as well as frequency-dependent storage modulus and the mechanical loss factor are obtained.
Mechanical Consequences of Dynamically Loaded NiTi Wires under Typical Actuator Conditions in Rehabilitation and Neuroscience
It turned out that a simple empirical relation could capture the characteristic temperature dependency of the storage modulus, which is an important input relation for modeling the rehabilitation device behavior under different dynamic and temperature loading conditions, taking directly into account the material behavior of the shape memory alloy.


Austenite–martensite interface in shape memory alloys
A two-scale phase field simulation is developed for austenite–martensite interface to understand the effects of crystalline symmetry and geometric compatibilities on the reversibility of structural
Phase Transformations of Nanocrystalline Martensitic Materials
The physical phenomena and engineering applications of martensitic phase transformations are the focus of intense ongoing research. The martensitic phase transformation and functional properties such
Surface tension and energy in multivariant martensitic transformations: phase-field theory, simulations, and model of coherent interface.
The Ginzburg-Landau theory for multivariant martensitic phase transformations is advanced in three directions: the potential is developed that introduces the surface tension at interfaces; a mixed
Phase-field approach to martensitic phase transformations: Effect of martensite–martensite interface energy
Abstract A generalization of the phase-field theory for multivariant martensitic phase transformations is suggested that allows one to vary martensite–martensite interface energy independent of