magnetoviscosity

Magnetoviscosity is the dependence of a magnetizable fluid’s viscosity on an applied magnetic field. It is most commonly studied in ferrofluids, which are colloidal suspensions of nanoscale magnetic particles stabilized by surfactants. When a magnetic field is applied, the particles acquire dipole moments that interact and tend to align along the field, forming transient chain- and column-like structures. This field-induced structuring increases the fluid’s resistance to flow, leading to a higher effective viscosity and, in some cases, a yield-stress-like response in concentrated suspensions. The effect is generally anisotropic, often producing greater resistance to shear parallel to the field than perpendicular to it.

Mechanisms and factors contributing to magnetoviscosity include the strength of the magnetic field, particle concentration and

Theoretical descriptions of magnetoviscosity are encompassed by ferrohydrodynamics, with models such as Shliomis and related approaches

Applications include vibration damping, sealing, and controllable fluidic systems where a magnetic field tunes rheological properties.