With the presence
of an external magnetic
field, a ferrofluid droplet exhibits a rich variety of interesting
phenomena notably different from nonmagnetic droplets. Here, a ferrofluid
droplet impacting on a liquid-repellent surface is systematically
investigated using high-speed imaging. The pre- and post-impact, including
the droplet stretching, maximum spreading diameter, and final impact
modes, are shown to depend on the impact velocity and the magnitude
of the external magnetic field. A scaling relation involving the Weber
and magnetic Bond numbers is fitted to predict the maximum spreading
diameter based on the magnetic field-induced effective surface tension.
The impact outcome is also investigated and classified into three
patterns depending on the occurrence of the rim interface instability
and the fission phenomenon. Two types of fission (i.e., evenly and
unevenly distributed sizes of the daughter droplets) are first identified,
and the corresponding mechanism is revealed. Last, according to Rayleigh–Taylor
instability, a semiempirical formula is proposed to estimate the number
of the daughter droplets in the regime of evenly distributed size,
which agrees well with the experimental data. The present study can
provide more insight into large-scale droplet generation with monodispersive
sizes.