An energy-based material model for the simulation of shape memory alloys under complex boundary value problems
DOI10.1016/J.CMA.2024.117134MaRDI QIDQ6588285
Tobias Bode, Philipp Junker, Cem Erdogan
Publication date: 15 August 2024
Published in: Computer Methods in Applied Mechanics and Engineering (Search for Journal in Brave)
finite element methodphase transformationthermo-mechanical couplingshape memory alloyvariational modeling
Finite element methods applied to problems in solid mechanics (74S05) Mathematical modeling or simulation for problems pertaining to mechanics of deformable solids (74-10)
Cites Work
- Title not available (Why is that?)
- Thermodynamic and relaxation-based modeling of the interaction between martensitic phase transformations and plasticity
- A 3-D phenomenological constitutive model for shape memory alloys under multiaxial loadings
- A macroscopic 1D model for shape memory alloys including asymmetric behaviors and transformation-dependent elastic properties
- Nonequilibrium thermodynamics of pseudoelasticity
- Finite deformation constitutive equations and a time integration procedure for isotropic, hyperelastic-viscoplastic solids
- On the calculation of energy-minimizing phase fractions in shape memory alloys
- Three-dimensional model for solids undergoing stress-induced phase transformations
- A thermodynamical constitutive model for shape memory materials. I: The monolithic shape memory alloy
- Finite deformation pseudo-elasticity of shape memory alloys -- constitutive modelling and finite element implementation
- A novel approach to representative orientation distribution functions for modeling and simulation of polycrystalline shape memory alloys
- On the Parametrization of the Three-Dimensional Rotation Group
- Computational Contact Mechanics
- A multi-variant martensitic phase transformation model: Formulation and numerical implementation
- Space-time variational material modeling: a new paradigm demonstrated for thermo-mechanically coupled wave propagation, visco-elasticity, elasto-plasticity with hardening, and gradient-enhanced damage
- An extended Hamilton principle as unifying theory for coupled problems and dissipative microstructure evolution
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