Based on the latest investigations on the formulation of new magneto-rheological fluids, it is envisioned that the use of
ionic liquids as carriers of magneto-rheological fluids will open new possibilities of applications for these smart fluids
due to the fact that their physical and chemical properties can be fine-tuned in a broad range. This contribution addresses
one potentially important advantage of magneto-rheological fluids which use ionic liquids as novel carriers. In
connection with this, magneto-rheological fluids with a low viscosity in the off-state without compromising other
properties of the formulations (e. g., sedimentation of the dispersed magnetic particles, liquid state of the carriers in a
broad range of temperatures) are often required for specific applications. In this regard, ionic liquids of low viscosity can
be very useful in the development of such magneto-rheological fluids. Thus, this contribution reports on the magnetorheological
properties of iron(II, III) oxide particles dispersed in the ionic liquid 1-ethyl-3-methylimidazolium
thiocyanate (a low viscosity ionic liquid) in the temperature range from 20 °C to 80 °C. The experimental results have
revealed that the apparent viscosity of the dispersion slightly changes with the temperature when a constant magnetic
field is applied and its value mainly depends on the shear rate and the strength of the magnetic field. The viscosity of the
dispersion remains practically unmodified with both the temperature and the magnetic field intensity as the magnetic
saturation of the material is reached; in this regime the viscosity will only depend on the applied shear rate. In contrast,
the yield stress values of the dispersion as well as the corresponding shear stress vs. shear rate curves have shown an
inverse behavior with temperature for a constant magnetic field.
A new method for the preparation of magnetorheological elastomers or solid composites with intriguing properties is
presented. The method makes use of magnetorheological fluids formed by micron-sized magnetic particles dispersed in
ionic liquids. These dispersions are combined with suitable polymers to obtain novel magnetoresponsive solid materials
which may find interesting applications, for instance, as actuators, in diverse fields of science and engineering.
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