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Your search keyword '"Yamanouchi, Takeru"' showing total 11 results
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11 results on '"Yamanouchi, Takeru"'

1. Elucidation of the trapping characteristics of magnetic disk-like particles in a Hagen-Poiseuille flow via Brownian dynamics simulations (usage of multi-magnetic poles).

Author

Yamanouchi, Takeru and Satoh, Akira

Subjects
*MAGNETIC traps, *MAGNETIC particles, *MAGNETIC pole, *GRANULAR flow, *MAGNETIC flux density, *BROWNIAN motion
Abstract

In the present study, we elucidate the behaviour of a suspension composed of magnetic disk-like particles that flow in a Hagen-Poiseuille flow in a gradient magnetic field and the trapping characteristics of the magnetic particles. To this end, we utilise multiple pairs of magnetic poles located outside the cylindrical system. Brownian dynamics simulations were performed in order to clarify the dependence of these characteristics on a variety of factors. It is seen that an increase in the magnetic field strength improves the trapping characteristics of disk-like particles if the influence of an applied magnetic field is sufficiently more dominant than that of a flow field and that of the magnetic particle-particle interaction. In the case of a strong magnetic particle-particle interaction, thin chain-like clusters are formed from an anchored particle trapped around a magnetic pole. If the two poles are sufficiently close to each other, an arch-type cluster is formed between them. We expect that this arch-type cluster may give rise to good trapping performance even in the presence of a strong flow field if the formation arises at a sufficiently large separation distance between the pair of magnetic poles. Highlights We have performed Brownian dynamics simulations for a magnetic disk-like particle suspension in a Hagen-Poiseuille flow. If the magnetic particle-particle interaction is sufficiently more dominant than the flow field, thin chain-like clusters are formed from an anchored particle. As the pole separation distance decreases, an arch-type configuration tends to be formed along the surface of the wall. This arch-type cluster that is formed between the pair of magnetic poles may be expected to improve the trapping characteristics depending on the pole separation distance. [ABSTRACT FROM AUTHOR]

Published
2024
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2. Control of the aggregate structure of magnetic cubic particles in a quasi-2D suspension via both the strength and direction of an applied magnetic field (multi-particle collision dynamics simulations).

Author

Satoh, Akira, Okada, Kazuya, Suzuki, Seiya, Yamanouchi, Takeru, Quadra, Rafael, and Futamura, Muneo

Subjects
MAGNETIC structure, MAGNETIC particles, MAGNETIC fields, MOLECULAR dynamics, MAGNETIC suspension, ROTATIONAL motion, PARTICLE acceleration
Abstract

We have first investigated a feasibility of a malt-particle collision dynamics (MPCD) method by addressing whether or not the translational and rotational Brownian motion is activated at a physically reasonable level. From the results with respect to the root mean square velocities, we conclude that the MPCD method is a quite feasible simulation technique for a suspension composed of magnetic cubic particles. Then we have applied the MPCD simulation method to a quasi-2D system of magnetic cubic particles in order to control a regime change in the internal structure of particle aggregates by means of the strength and direction of a uniform applied magnetic field. In the case of a magnetic field applied in a certain direction from the 2D plane, a regime change in the internal structure of large densely-packed clusters into a regular configuration is more effectively attained than a magnetic field applied along the 2D plane. [ABSTRACT FROM AUTHOR]

Published
2023
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8. Improvement of trapping performance of magnetic particles by magnetic multi-poles via Brownian dynamics simulations of magnetic rod-like particles in a Hagen-Poiseuille flow.

Author

Yamanouchi, Takeru and Satoh, Akira

Subjects
*MAGNETIC traps, *MAGNETIC particles, *GRANULAR flow, *MAGNETIC pole, *BROWNIAN motion, *MAGNETIC flux density
Abstract

In the present study we have implemented a Brownian dynamics simulation of a Hagen-Poiseuille flow in a cylindrical vessel and have investigated the feasibility of multi-pairs of magnetic poles for exhibiting a good particle trapping performance. We have focused on two representative types of configuration consisting of two pairs of magnetic poles. The first is a vertical configuration of two pairs of poles arranged perpendicular to the direction of the flow field. The second is a parallel configuration, where each pair of magnetic poles is arranged along the surface of the vessel wall. In the case of the vertical pole arrangement, although densely-packed aggregates were formed between the poles, their location was unstable in the flow field and they tended to be carried away downstream. In contrast, a densely-packed cluster formed in the parallel arrangement tended locate in a more stable manner along the surface of the wall where the flow field is weaker. We conclude that under appropriate conditions of the magnetic particle-particle interaction strength, the applied magnetic field strength and the pole separation distance, the parallel arrangement of magnetic poles is the configuration of choice for giving rise to a superior trapping performance. [ABSTRACT FROM AUTHOR]

Published
2022
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