Experimental and Theoretical Investigation on the Dynamic Response of Ferrofluid Liquid Marbles to Steady and Pulsating Magnetic Fields

Mohammadrashidi, Mahbod; Bijarchi, Mohamad Ali; Taghipoor, Mojtaba

doi:10.1021/acs.langmuir.2c02811

Cited by 12 publications

(12 citation statements)

References 67 publications

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“…Azizian et al 50 proposed a new approach, inspired by billiard ball collisions, for liquid marble manipulation by driving an FM to collide with a non-magnetic LM. Mohammadrashidi et al 51 experimentally investigated the dynamic behavior of ferrofluid liquid marbles on a solid substrate under magnetic fields, in which the LM undergoes discontinuous, less-controllable movement. Since LMs could be controlled on a solid surface or float on the water surface, [15][16][17][18] it has been demonstrated that marbles experience rolling when they are in contact with a solid surface, whereas floating marbles could undergo sliding motions, which is the preferred operating situation in DMF.…”

Section: Demonstrated That Magnetic Nanoparticles Have An Inhibitory ...mentioning

confidence: 99%

“…Unlike naked ferrofluid droplets, manipulating biocompatible LMs such as LMMSs is not fully understood, especially when they move on the water surface driven by a time-varying magnetic field. In this regard, FMs have attracted the attention of researchers more than LMMSs; 28,46,51 however, LMMSs could be preferable based on their higher biocompatibility, as magnetic nanoparticles and surfactants are in less contact with the biological cargo in the core fluid. 29,[54][55][56] The integration of electromagnets with a pulse-widthmodulation (PWM) circuit is promising as a stimulus for the manipulation of floating magnetic LMs.…”

Section: Demonstrated That Magnetic Nanoparticles Have An Inhibitory ...mentioning

confidence: 99%

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Dynamic behavior of floating magnetic liquid marbles under steady and pulse-width-modulated magnetic fields

Dayyani,

Mohseni,

Bijarchi

2024

Lab Chip

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Section: Demonstrated That Magnetic Nanoparticles Have An Inhibitory ...mentioning

confidence: 99%

Section: Demonstrated That Magnetic Nanoparticles Have An Inhibitory ...mentioning

confidence: 99%

Dynamic behavior of floating magnetic liquid marbles under steady and pulse-width-modulated magnetic fields

Dayyani,

Mohseni,

Bijarchi

2024

Lab Chip

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“…While such “smart” machines can be actuated by different stimuli, magnetic fields appear to be particularly attractive for their precise controllability and efficacy in realizing a wide variety of shapes and functionalities. , The most common variant of such a micromachine can simply be a liquid drop made of a suspension of magnetic nanoparticles commonly known as ferrofluids. Despite being elusively simple to synthesize, the ferrofluids offer great promise in a wide variety of automated applications ranging from liquid cargo delivery, − cell and tissue engineering, , water purification to on-chip mixing of liquid samples . Although their different shape modulations, splitting, and merging were successfully demonstrated in previous works, the proposition of tuning their wettability at will, preferably in a programmable manner, continues to offer an outstanding challenge when the applied field strength exceeds the saturation magnetization limit.…”

Section: Introductionmentioning

confidence: 99%

Switchable Wettability States of a Ferrofluid Droplet atop a Hydrophobic Interface

Bhattacharjee,

Atta,

Chakraborty

2024

J. Phys. Chem. B

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Magnetically tuned soft machines offer great promise in performing a wide variety of programmable tasks via their dynamic shape adaptation and alteration. Despite dramatic recent advancements in this regard, selective reconfiguration of the wetting behavior of a ferrofluid droplet atop a hydrophobic interface adapted as a magnetically modulated micromachine remained elusive when the applied field intensity exceeds the saturation magnetization. Here we unveil a strategy to unsettle this perspective by harnessing a magnetic field-dependent magnetization phenomenon that may be exploited exclusively to arrive at highly controllable dynamic switchable wetting states of ferrofluid droplets, including the realization of wide ranges of contact angles for a given applied magnetic field. We arrive at a physical law from the resulting interplay of forces that quantifies the time dependence of the contact angle variation for a given magnetic field. Substantiated by experimental findings, our multiphysics-based simulations further evidence the possibilities of realizing switchable wetting states of soft magnetic matter over a wide range of physical parameters, delving into this principle. Disrupting the established notion of a trivially unique wetting phenomenon as governed by the droplet-substrate combination and the applied field alone, this paradigm may thus benefit a wide variety of practical applications, ranging from digital microfluidics to recombination chemistry.

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“…Mohammadrashidi et al theoretically and experimentally studied the motion dynamics of ferrofluid marbles under steady and unsteady magnetic fields. They also observed the launching motion of ferrofluid marble by applying a single-pulse magnetic field . Azizian et al studied the collision of a ferrofluid marble with a water marble and examined the potential of using this collision for manipulating non-magnetic liquid marbles .…”

Section: Introductionmentioning

confidence: 99%

“…They also observed the launching motion of ferrofluid marble by applying a single-pulse magnetic field. 66 Azizian et al studied the collision of a ferrofluid marble with a water marble and examined the potential of using this collision for manipulating non-magnetic liquid marbles. 67 Yang et al investigated the reciprocating motion of ferrofluid marbles floating on the water surface.…”

Section: ■ Introductionmentioning

confidence: 99%

Vibration and Jumping of Ferrofluid Marbles under an Initial Magnetic Perturbation

et al. 2023

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Liquid marbles are being promoted as a replacement for conventional droplets in digital microfluidics. Liquid marbles can be remotely controlled by an external magnetic field if ferrofluid is utilized as their liquid cores. In this study, the vibration and jumping of a ferrofluid marble is experimentally and theoretically investigated. An external magnetic field is utilized to induce deformation in a liquid marble and an increase in its surface energy. As the magnetic field is switched off, the stored surface energy converts to gravitational potential and kinetic energies until it is dissipated. An equivalent linear mass-spring-damper system is used to study the vibration of the liquid marble, and the effect of its volume and initial magnetic stimulus on the vibrational characteristics, such as natural frequency, damping ratio, and deformation of the liquid marble, is experimentally examined. By analyzing these oscillations, the effective surface tension of the liquid marble is evaluated. Also, a novel theoretical model is proposed to obtain the damping ratio of the liquid marble, suggesting a new tool for the measurement of liquid viscosity. Interestingly, it is observed that the liquid marble jumps from the surface in the case of high initial deformation. Based on conservation law of energy, a theoretical model for predicting the liquid marbles jumping height and the boundary between jumping and non-jumping zones in terms of nondimensional numbers, namely, magnetic and gravitational Bond numbers and Ohnesorge number, is proposed with an acceptable error compared to experimental data.

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Experimental and Theoretical Investigation on the Dynamic Response of Ferrofluid Liquid Marbles to Steady and Pulsating Magnetic Fields

Cited by 12 publications

References 67 publications

Dynamic behavior of floating magnetic liquid marbles under steady and pulse-width-modulated magnetic fields

Dynamic behavior of floating magnetic liquid marbles under steady and pulse-width-modulated magnetic fields

Switchable Wettability States of a Ferrofluid Droplet atop a Hydrophobic Interface

Vibration and Jumping of Ferrofluid Marbles under an Initial Magnetic Perturbation

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