Levitation of non-magnetizable droplet inside ferrofluid

Abstract: The central theme of this work is that a stable levitation of a denser non-magnetizable liquid droplet, against gravity, inside a relatively lighter ferrofluid -a system barely considered in ferrohydrodynamics -is possible, and exhibits unique interfacial features; the stability of the levitation trajectory, however, is subject to an appropriate magnetic field modulation. We explore the shapes and the temporal dynamics of a plane non-magnetizable droplet levitating inside ferrofluid against gravity due to a sp… Show more

“…Singh et al. (2018) followed a similar approach to investigate the motion of a water droplet in a saturated ferrofluid.…”

“…A dynamical analysis of the linearization of system (5.2) reveals that depending on the problem parameters, the nature of motion of particle in the vicinity of its equilibrium position is monotonic or oscillatory (for details of the dynamical analysis, the reader is referred to appendix A). Singh et al (2018) followed a similar approach to investigate the motion of a water droplet in a saturated ferrofluid.…”

“…When a particle is allowed to move freely under the combined effect of the magnetic buoyancy force and gravity, new features can occur in the particle motion. Singh, Das & Das (2018) used a one-fluid numerical model to explore the centre of mass and interface dynamics of an almost neutrally buoyant droplet (mass density ratio of ) levitating in a ferrofluid. By approximating the vertical motion of the droplet by a simple dynamical model, the authors showed that depending on the parameters of the considered magnetofluidic set-up, the behaviour of vertical droplet motion can be monotonic or oscillating.…”

Direct numerical simulation of magneto-Archimedes separation of spherical particles

“…Singh et al. (2018) followed a similar approach to investigate the motion of a water droplet in a saturated ferrofluid.…”

“…A dynamical analysis of the linearization of system (5.2) reveals that depending on the problem parameters, the nature of motion of particle in the vicinity of its equilibrium position is monotonic or oscillatory (for details of the dynamical analysis, the reader is referred to appendix A). Singh et al (2018) followed a similar approach to investigate the motion of a water droplet in a saturated ferrofluid.…”

“…When a particle is allowed to move freely under the combined effect of the magnetic buoyancy force and gravity, new features can occur in the particle motion. Singh, Das & Das (2018) used a one-fluid numerical model to explore the centre of mass and interface dynamics of an almost neutrally buoyant droplet (mass density ratio of ) levitating in a ferrofluid. By approximating the vertical motion of the droplet by a simple dynamical model, the authors showed that depending on the parameters of the considered magnetofluidic set-up, the behaviour of vertical droplet motion can be monotonic or oscillating.…”

Direct numerical simulation of magneto-Archimedes separation of spherical particles

“…The passive approach entirely depends on the molecular diffusion between the phases to be mixed and can be tuned by altering the surface morphology (for example, a patterned wettability controlled surface) towards achieving the desired controllability of the mixing (Xing, Harake & Pan 2011;de Groot et al 2016). While the active approach, which is more prevalent due to its reconfigurable flexibility, primarily relies on external force fields such as an electric field, magnetic field, acoustic waves and light energy for manoeuvring the flow velocities inside the droplet domain (Shang, Cheng & Zhao 2017;Meng & Colonius 2018;Singh, Das & Das 2018;Behera, Mandal & Chakraborty 2019;Grassia 2019).…”

“…While the active approach, which is more prevalent due to its reconfigurable flexibility, primarily relies on external force fields such as electric field, magnetic field, acoustic waves, and light energy for maneuvering the droplet flow field (Behera et al 2019;Grassia 2019;Meng & Colonius 2018;Shang et al 2017;Singh et al 2018).…”

Magnetofluidic mixing of a ferrofluid droplet under the influence of a time-dependent external field

A droplet in a ferrofluid droplet under a rotating magnetic field