Ferrofluid droplet manipulation using an adjustable alternating magnetic field

[Display omitted] •The alternating magnetic field is utilized for droplet manipulation.•A water-based ferrofluid with bio-compatible surfactant is used.•An analytical model is presented for droplet manipulation on hydrophobic surfaces.•Droplet manipulation and mixing are studied on a hydrophobic sur...

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Bibliographic Details
Published in:Sensors and actuators. A. Physical. 2020-01, Vol.301, p.111753, Article 111753
Main Authors: Bijarchi, Mohamad Ali, Favakeh, Amirhossein, Sedighi, Erfan, Shafii, Mohammad Behshad
Format: Article
Language:English
Subjects:
Alternating magnetic field
Biomedical engineering
Droplet manipulation
Droplets
Drug delivery systems
Ferrofluid
Ferrofluids
Flux density
Hydrophobic surfaces
Hydrophobicity
Magnetic coils
Magnetic digital microfluidics
Magnetic fields
Magnetic flux
Magnetism
Magnets
Mathematical models
Surface chemistry
Tissue engineering
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Summary:[Display omitted] •The alternating magnetic field is utilized for droplet manipulation.•A water-based ferrofluid with bio-compatible surfactant is used.•An analytical model is presented for droplet manipulation on hydrophobic surfaces.•Droplet manipulation and mixing are studied on a hydrophobic surface and in oil.•Alternating magnetic field can be considered as an alternative for previous methods. Magnetically actuated droplet manipulation offers a promising tool for biomedical and engineering applications, such as drug delivery, biochemistry, sample handling in lab-on-chip devices and tissue engineering. In this study, characteristics of an adjustable alternating magnetic field generated by a magnetic coil for droplet manipulation was investigated which enables more control on droplet transport, and it can be considered as a suitable alternative for moving magnets or an array of micro-coils. By adjusting the magnetic flux density, the duty cycle and applied magnetic frequency, the manipulation of water-based ferrofluid droplets with a bio-compatible surfactant for different volumes was comprehensively examined. Also, the platform was able to manipulate the ferrofluid droplets completely immersed in oil. This solves the problem with droplet evaporation which has previously been reported for droplet manipulation on the surface. Furthermore, an analytical model is proposed for the movement of the ferrofluid droplet on the hydrophobic surface. The model predictions are in good agreement with experimental results. Also, the effects of magnetic flux density, duty cycle, frequency and the distance between the coils on the mixing process were studied. Results showed that the droplet movement on the hydrophobic surface was fully synchronized with the generated signal while the droplet moved backward in the oil after the magnetic field was turned off. By decreasing magnetic flux density, droplet volume, duty cycle, as well as increasing applied magnetic frequency, the step lengths become more uniform, the resolution of droplet displacement increases, but the average-velocity decreases.
ISSN:0924-4247
1873-3069
DOI:10.1016/j.sna.2019.111753