Tunable Superparamagnetic Ring (tSPRing) for Droplet Manipulation

The manipulation of droplets via a magnetic field forms the basis of a fascinating technology that is currently in development. Often, the movement of droplets with magnets involves adding magnetic particles in or around the droplet; alternatively, magneto responsive surfaces may also be used. This...

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Veröffentlicht in:	Advanced functional materials 2021-08, Vol.31 (32), p.n/a
Hauptverfasser:	Nasirimarekani, Vahid, Benito‐Lopez, Fernando, Basabe‐Desmonts, Lourdes
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Sprache:	eng
Schlagworte:	Dipoles droplet manipulation Droplets Ferrofluids Ferromagnetism Magnetic fields magnetic particles Magnets Materials science Microfluidics Robust control Water drops
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description	The manipulation of droplets via a magnetic field forms the basis of a fascinating technology that is currently in development. Often, the movement of droplets with magnets involves adding magnetic particles in or around the droplet; alternatively, magneto responsive surfaces may also be used. This work, presents and characterizes experimentally the formation and properties of a tunable superparamagnetic ring (tSPRing), which precisely adjusts itself around a water droplet, due to liquid–liquid interaction, and enables the physical manipulation of droplets. The ring is made of an oil‐based ferrofluid, a stable suspension of ferromagnetic particles in an oily phase. It appears spontaneously due to the oil–water interfacial interaction under the influence of a magnetic field. The ferrofluid–water interaction resembles a cupcake assembly, with the surrounding ring only at the base of the droplet. The ring is analogous to a soft matter ring magnet, showing dipole repulsive forces, which stabilizes the droplets on a surface. It enables robust, controllable, and programmable manipulation of enclosed water droplets. This work opens the door to new applications in open surface upside or upside‐down microfluidics and lays the groundwork for new studies on tunable interfaces between two immiscible liquids. Ferrofluid instabilities shape as a ring around a water droplet. The assembly takes the shape of a cupcake and allows precise movement of the droplet on a surface, even on inverted surfaces. The ring behaves like a soft matter dipole, disappearing once the field is removed. It is a switchable tool for microfluidic applications such as droplet handling and mixing.
doi_str_mv	10.1002/adfm.202100178
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subjects	Dipoles droplet manipulation Droplets Ferrofluids Ferromagnetism Magnetic fields magnetic particles Magnets Materials science Microfluidics Robust control Water drops
title	Tunable Superparamagnetic Ring (tSPRing) for Droplet Manipulation
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