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Main Authors: Lanthaler, Samuel, Weber, Franziska
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.03099
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author Lanthaler, Samuel
Weber, Franziska
author_facet Lanthaler, Samuel
Weber, Franziska
contents Ferrofluids are a class of materials that exhibit both fluid and magnetic properties. We consider a two-phase diffuse interface model for the dynamics of ferrofluids on a bounded domain. One phase is assumed to be magnetic, the other phase can be magnetic or non-magnetic. We derive a coupled system of partial differential equations consisting of the incompressible Navier-Stokes equations, an evolution equation for the magnetization, the magnetostatics equations for the magnetic field and the Cahn-Hilliard equations for the evolution of the phase field variable, which are all coupled through various source terms and parameters. In contrast to similar models in the literature, the system in this work formally satisfies an energy balance which remains meaningful even in singular limits such as a limit of zero relaxation time. However, the formal derivation of this balance requires a delicate cancellation of several highly non-linear terms, making it challenging to ensure similar cancellations for approximating systems. Our first main result is to prove the existence of global weak solutions for our ferrofluid system based on a carefully constructed sequence of approximation steps. Additionally, we also study the relaxation towards the quasi-equilibrium, in which case the magnetization equation degenerates to a linear relation between the magnetic field and the magnetization. As our second main result, we prove the rigorous convergence to this limiting system.
format Preprint
id arxiv_https___arxiv_org_abs_2507_03099
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Global existence of weak solutions to a two-phase diffuse interface model of ferrofluids dynamics
Lanthaler, Samuel
Weber, Franziska
Analysis of PDEs
Ferrofluids are a class of materials that exhibit both fluid and magnetic properties. We consider a two-phase diffuse interface model for the dynamics of ferrofluids on a bounded domain. One phase is assumed to be magnetic, the other phase can be magnetic or non-magnetic. We derive a coupled system of partial differential equations consisting of the incompressible Navier-Stokes equations, an evolution equation for the magnetization, the magnetostatics equations for the magnetic field and the Cahn-Hilliard equations for the evolution of the phase field variable, which are all coupled through various source terms and parameters. In contrast to similar models in the literature, the system in this work formally satisfies an energy balance which remains meaningful even in singular limits such as a limit of zero relaxation time. However, the formal derivation of this balance requires a delicate cancellation of several highly non-linear terms, making it challenging to ensure similar cancellations for approximating systems. Our first main result is to prove the existence of global weak solutions for our ferrofluid system based on a carefully constructed sequence of approximation steps. Additionally, we also study the relaxation towards the quasi-equilibrium, in which case the magnetization equation degenerates to a linear relation between the magnetic field and the magnetization. As our second main result, we prove the rigorous convergence to this limiting system.
title Global existence of weak solutions to a two-phase diffuse interface model of ferrofluids dynamics
topic Analysis of PDEs
url https://arxiv.org/abs/2507.03099