Abstract
The mathematical and physical analysis of magnetoelastic phenomena is a topic of ongoing research. Different formulae have been proposed to describe the magnetic forces in macroscopic systems. We discuss several of these formulae in the context of rigid magnetized bodies. In case the bodies are in contact, we consider formulae both in the framework of macroscopic electrodynamics and via a multiscale approach, i.e., in a discrete setting of magnetic dipole moments. We give mathematically rigorous proofs for domains of polygonal shape (as well as for more general geometries) in two and three space dimensions. In an accompanying second article, we investigate the formulae in a number of numerical experiments, where we focus on the dependence of the magnetic force on the distance between the bodies and on the case when the two bodies are in contact. The aim of the analysis as well as of the numerical simulation is to contribute to the ongoing debate about which formula describes the magnetic force between macroscopic bodies best and to stimulate corresponding real-life experiments.
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Communicated by A. DeSimone
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Popović, N., Praetorius, D. & Schlömerkemper, A. Analysis and numerical simulation of magnetic forces between rigid polygonal bodies. Part I: Analysis. Continuum Mech. Thermodyn. 19, 67–80 (2007). https://doi.org/10.1007/s00161-007-0046-9
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DOI: https://doi.org/10.1007/s00161-007-0046-9
Keywords
- Magnetostatics
- Magnetic force formulae
- Potential theory
- Partial differential equations
- Lattice-to-continuum limit