Three-dimensional self-assembly using dipolar interaction

Leon Abelmann; Tijmen Hageman; Per Löthman; Massimo Mastrangeli; Miko Elwenspoek

doi:10.48550/arXiv.2005.04391

Three-dimensional self-assembly using dipolar interaction

Leon Abelmann, Tijmen Hageman, Per Löthman, Massimo Mastrangeli, Miko Elwenspoek

Robotics and Mechatronics

Research output: Working paper › Preprint › Academic

Abstract

Interaction between dipolar forces, such as permanent magnets, generally leads to the formation of one-dimensional chains and rings. We investigated whether it was possible to let dipoles self-assemble into three-dimensional structures by encapsulating them in a shell with a specific shape. We found that the condition for self-assembly of a three-dimensional crystal is satisfied when the energies of dipoles in the parallel and antiparallel states are equal. Our experiments show that the most regular structures are formed using cylinders and cuboids and not by spheroids. This simple design rule will help the self-assembly community to realize three-dimensional crystals from objects in the micrometer range, which opens up the way toward previously unknown metamaterials.

Original language	English
Publisher	ArXiv.org
DOIs	https://doi.org/10.48550/arXiv.2005.04391
Publication status	Published - 9 May 2020

Keywords

physics.app-ph
cond-mat.soft

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10.48550/arXiv.2005.04391

2005.04391v1Final published version, 352 KB

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Three-dimensional self-assembly using dipolar interaction
Abelmann, L., Hageman, T. A. G., Löthman, P. A., Mastrangeli, M. & Elwenspoek, M. C., 8 May 2020, In: Science advances. 6, 19, 4 p., eaba2007.
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abstract = " Interaction between dipolar forces, such as permanent magnets, generally leads to the formation of one-dimensional chains and rings. We investigated whether it was possible to let dipoles self-assemble into three-dimensional structures by encapsulating them in a shell with a specific shape. We found that the condition for self-assembly of a three-dimensional crystal is satisfied when the energies of dipoles in the parallel and antiparallel states are equal. Our experiments show that the most regular structures are formed using cylinders and cuboids and not by spheroids. This simple design rule will help the self-assembly community to realize three-dimensional crystals from objects in the micrometer range, which opens up the way toward previously unknown metamaterials. ",

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AU - Elwenspoek, Miko

N1 - 4 pages

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AB - Interaction between dipolar forces, such as permanent magnets, generally leads to the formation of one-dimensional chains and rings. We investigated whether it was possible to let dipoles self-assemble into three-dimensional structures by encapsulating them in a shell with a specific shape. We found that the condition for self-assembly of a three-dimensional crystal is satisfied when the energies of dipoles in the parallel and antiparallel states are equal. Our experiments show that the most regular structures are formed using cylinders and cuboids and not by spheroids. This simple design rule will help the self-assembly community to realize three-dimensional crystals from objects in the micrometer range, which opens up the way toward previously unknown metamaterials.

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KW - cond-mat.soft

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BT - Three-dimensional self-assembly using dipolar interaction

PB - ArXiv.org

ER -

Three-dimensional self-assembly using dipolar interaction

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Three-dimensional self-assembly using dipolar interaction

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