Abstract

We have investigated a suspension composed of spherical magnetic Janus particles in thermodynamic equilibrium. The magnetic moment of Janus particles treated here is located at a position shifted from the particle centre, which is on the line perpendicular to the magnetic moment direction. We conducted quasi-2D Monte Carlo simulations to investigate the change in the regime of aggregate structures and the dependence of the regime on various factors, such as the strength of the magnetic particle-particle interaction, magnetic particle-field interaction, and the distance of the magnetic moment from the particle centre. In the absence of an applied magnetic field, the Janus particles aggregate to form stable clusters composed of a few particles with increased values of the magnetic particle-particle interaction strength. As the strength of the magnetic field is increased, these clusters collapse, and chain-like clusters are formed aligned in the direction of the magnetic field. The appearance of this regime change requires a stronger magnetic field as the position of the magnetic moment approaches the particle surface. This can be attributed to the fact that the magnetic interaction between neighbouring particles becomes more dominant as the magnetic moments of the constituent particles in the cluster units approach each other. Highlights We have addressed the aggregation phenomena in a suspension composed of spherical magnetic Janus particles. We have investigated the regime change in the aggregate structures of the Janus particles under various conditions. In a strong magnetic field, thick chain-like clusters are formed as the magnetic moment is shifted away from the particle centre. The present results are useful for elucidating the internal structure of complex aggregates in 3D systems.

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