Formation and dynamics of droplets in a magnetic fluid in microchannels in an inhomogeneous magnetic field of ring magnet

D. A. Kalyuzhnaya; Калюжная Д. А.; E. A. Sokolov; Соколов Е. А.; G. A. Zhukov; Жуков Г. А.; P. A. Ryapolov; Ряполов П. А.

doi:10.31857/S0367676524100162

Formation and dynamics of droplets in a magnetic fluid in microchannels in an inhomogeneous magnetic field of ring magnet

作者: Kalyuzhnaya D.A.¹, Sokolov E.A.¹, Zhukov G.A.¹, Ryapolov P.A.¹
隶属关系:
1. Southwest State University
期: 卷 88, 编号 10 (2024)
页面: 1607-1613
栏目: Microfluidics and ferrohydrodynamics of magnetic colloids
URL: https://journals.rcsi.science/0367-6765/article/view/283398
DOI: https://doi.org/10.31857/S0367676524100162
EDN: https://elibrary.ru/DSKQEX
ID: 283398

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We studied the dynamics of non-magnetic droplets in magnetic liquids in microchannels with a “flow focusing” configuration under the action of an inhomogeneous magnetic field of an annular magnet. Two types of multiphase systems were studied: non-magnetic emulsions “oil in water”, “water in oil”, as well as “water in oil in water” and magnetic direct emulsions in which the magnetic liquid was used as a continuous phase. The dependences of the sizes of the generated non-magnetic inclusions on the flow rate of the continuous magnetic phase and the displacement of the magnetic field source relative to the dispersed phase supply connector horizontally along the channel axis are obtained.

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microfluidics, emulsion, wall wettability, microfluidic chip, droplet dynamics, magnetic fluids

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作者简介

D. Kalyuzhnaya

Southwest State University

Email: r-piter@yandex.ru
俄罗斯联邦, Kursk

E. Sokolov

Southwest State University

Email: r-piter@yandex.ru
俄罗斯联邦, Kursk

G. Zhukov

Southwest State University

Email: r-piter@yandex.ru
俄罗斯联邦, Kursk

P. Ryapolov

Southwest State University

编辑信件的主要联系方式.
Email: r-piter@yandex.ru
俄罗斯联邦, Kursk

参考

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2. Fig. 1. Experimental setup: external appearance (a); block diagram (b): 1 — microfluidic device, 2 — ring permanent magnet, 3,4 — syringe pump, 5 — digital microscope, 6 — illuminator, 7 — computer, 8 — mechatronic drive.

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3. Fig. 2. Configuration of microfluidic devices: chip for single emulsions (a): 1 — connector for feeding the continuous phase, 2 — connector for feeding the dispersed phase, 3 — output connector; chip for double emulsions (b): 1 — connector for feeding the external phase. The region of magnetic levitation at the zero position of the ring magnet is highlighted in green, 2 — connector for feeding the middle phase, 3 — connector for feeding the internal phase, 4 — output connector.

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4. Fig. 3. Spatial distribution of isolines of the modulus of the inhomogeneous magnetic field in the Cartesian coordinate system, the center of which is the center of symmetry of the magnet: for Magnet 1 (a); for Magnet 2 (b).

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5. Fig. 4. Emulsions in microchannels: single direct emulsion (a); single inverse emulsion (b); double emulsion “water/oil/water” [22] (c).

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6. Fig. 5. Dynamics of mineral oil droplets in a sample of magnetic fluid МЖ-1 at different feed rates of the continuous phase q1 under the action of the magnetic field of the ring Magnet1, located in the zero position relative to the connector for feeding the dispersed phase into the microchannel.

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7. Fig. 6. Dependences of the volume of oil droplets in a microfluidic chip: on the flow rate of magnetic fluid МЖ-1 (a); on the movement of magnets (b).

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8. Fig. 7. Dependence of the volume of mineral oil drops on the movement of magnets for a sample of magnetic fluid МЖ-2.

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卷 88, 编号 12 (2024)

卷 88, 编号 12 (2024)

Formation and dynamics of droplets in a magnetic fluid in microchannels in an inhomogeneous magnetic field of ring magnet

全文:

详细

关键词

全文:

作者简介

D. Kalyuzhnaya

E. Sokolov

G. Zhukov

P. Ryapolov

参考

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