Modeling the dynamic magneto-mechanical response of magnetic shape memory alloys based on Hamilton's principle: the governing equation system
DOI10.1016/j.jmps.2021.104761zbMath1514.74028OpenAlexW4205519484MaRDI QIDQ6162011
Chengkai Fan, Paul Steinmann, Jiong Wang
Publication date: 28 June 2023
Published in: Journal of the Mechanics and Physics of Solids (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.jmps.2021.104761
dynamic responseHamilton's principleconstitutive modelingmagnetic shape memory alloysvariant reorientation
Electromagnetic effects in solid mechanics (74F15) Materials of strain-rate type and history type, other materials with memory (including elastic materials with viscous damping, various viscoelastic materials) (74D99)
Cites Work
- Generalized Hamilton's principle for inelastic bodies within non-equilibrium thermodynamics
- An admissibility condition for equilibrium shocks in finite elasticity
- A continuum thermodynamics formulation for micro-magneto-mechanics with applications to ferromagnetic shape memory alloys
- The elastic energy-momentum tensor
- Views on multiplicative elastoplasticity and the continuum theory of dislocations
- On the modeling of equilibrium twin interfaces in a single-crystalline magnetic shape memory alloy sample. II: Numerical algorithm
- On the modeling of equilibrium twin interfaces in a single-crystalline magnetic shape-memory alloy sample. III: Magneto-mechanical behaviors
- On the modeling of equilibrium twin interfaces in a single-crystalline magnetic shape memory alloy sample. I: Theoretical formulation
- On Variational Formulations in Nonlinear Magnetoelastostatics
- Rearrangement of martensitic variants in \(ni_2\) mnga studied with the phase-field method
- Unnamed Item
This page was built for publication: Modeling the dynamic magneto-mechanical response of magnetic shape memory alloys based on Hamilton's principle: the governing equation system
