Statics and dynamics of magnetocapillary bonds

Guillaume Lagubeau; Galien Grosjean; Alexis Darras; Geoffroy Lumay; Maxime Hubert; Nicolas Vandewalle

doi:10.1103/PhysRevE.93.053117

Statics and dynamics of magnetocapillary bonds

Guillaume Lagubeau, Galien Grosjean, Alexis Darras, Geoffroy Lumay, Maxime Hubert, Nicolas Vandewalle

School of Physics

Research output: Contribution to journal › Article (Academic Journal) › peer-review

14 Citations (Scopus)

Abstract

When ferromagnetic particles are suspended at an interface under magnetic fields, dipole-dipole interactions compete with capillary attraction. This combination of forces has recently given promising results towards controllable self-assemblies as well as low-Reynolds-number swimming systems. The elementary unit of these assemblies is a pair of particles. Although equilibrium properties of this interaction are well described, the dynamics remain unclear. In this paper, the properties of magnetocapillary bonds are determined by probing them with magnetic perturbations. Two deformation modes are evidenced and discussed. These modes exhibit resonances whose frequencies can be detuned to generate nonreciprocal motion. A model is proposed that can become the basis for elaborate collective behaviors.

Original language	English
Article number	053117
Journal	Physical Review E
Volume	93
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.93.053117
Publication status	Published - 31 May 2016

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© 2016 American Physical Society.

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abstract = "When ferromagnetic particles are suspended at an interface under magnetic fields, dipole-dipole interactions compete with capillary attraction. This combination of forces has recently given promising results towards controllable self-assemblies as well as low-Reynolds-number swimming systems. The elementary unit of these assemblies is a pair of particles. Although equilibrium properties of this interaction are well described, the dynamics remain unclear. In this paper, the properties of magnetocapillary bonds are determined by probing them with magnetic perturbations. Two deformation modes are evidenced and discussed. These modes exhibit resonances whose frequencies can be detuned to generate nonreciprocal motion. A model is proposed that can become the basis for elaborate collective behaviors.",

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AU - Lagubeau, Guillaume

AU - Grosjean, Galien

AU - Darras, Alexis

AU - Lumay, Geoffroy

AU - Hubert, Maxime

AU - Vandewalle, Nicolas

PY - 2016/5/31

Y1 - 2016/5/31

N2 - When ferromagnetic particles are suspended at an interface under magnetic fields, dipole-dipole interactions compete with capillary attraction. This combination of forces has recently given promising results towards controllable self-assemblies as well as low-Reynolds-number swimming systems. The elementary unit of these assemblies is a pair of particles. Although equilibrium properties of this interaction are well described, the dynamics remain unclear. In this paper, the properties of magnetocapillary bonds are determined by probing them with magnetic perturbations. Two deformation modes are evidenced and discussed. These modes exhibit resonances whose frequencies can be detuned to generate nonreciprocal motion. A model is proposed that can become the basis for elaborate collective behaviors.

AB - When ferromagnetic particles are suspended at an interface under magnetic fields, dipole-dipole interactions compete with capillary attraction. This combination of forces has recently given promising results towards controllable self-assemblies as well as low-Reynolds-number swimming systems. The elementary unit of these assemblies is a pair of particles. Although equilibrium properties of this interaction are well described, the dynamics remain unclear. In this paper, the properties of magnetocapillary bonds are determined by probing them with magnetic perturbations. Two deformation modes are evidenced and discussed. These modes exhibit resonances whose frequencies can be detuned to generate nonreciprocal motion. A model is proposed that can become the basis for elaborate collective behaviors.

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VL - 93

JO - Physical Review E

JF - Physical Review E

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ER -

Statics and dynamics of magnetocapillary bonds

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