Dynamics of Aggregation Processes and Electrophysical Properties of Transformer Oil-Based Magnetic Fluids

TL;DR

This study explores how transformer oil-based magnetic fluids' microstructure and dielectric properties evolve under magnetic fields, revealing how nanoparticle concentration and temperature influence aggregation and potential applications in sensors and adaptive devices.

Contribution

It provides new insights into the dynamic aggregation behavior and dielectric response of magnetic fluids under varying magnetic fields and temperatures.

Findings

Dielectric permittivity increases linearly at low nanoparticle concentrations.

Higher concentrations cause conductivity saturation and dispersion effects.

Aggregate reorientation dynamics are critical for device design.

Abstract

Magnetic fluids exhibit tunable structures and electrophysical properties, making them promising for adaptive optical systems, biomedical sensors, and microelectromechanical devices. However, the dynamic evolution of their microstructure under varying magnetic fields remains insufficiently explored. This study investigates the structural and dielectric properties of transformer oil-based magnetic fluids containing 0.2-10 vol% magnetite nanoparticles, across a frequency range of 20 Hz to 10 MHz. Particular attention is given to the dynamics of aggregate reorientation in response to alternating magnetic fields. Experimental results demonstrate that low nanoparticle concentrations lead to a linear increase in dielectric permittivity and conductivity, consistent with the Maxwell-Wagner model. In contrast, higher concentrations exhibit conductivity saturation and dispersion effects due to the formation of elongated aggregates. An analysis based on the Boyle polarization model describes the relaxation and structural changes associated with aggregation dynamics. Changes in the magnetic field orientation induce aggregate reconfiguration and significant structural transformations. At early stages, elongated chains form, subsequently thickening until an equilibrium state is reached. Elevated temperatures accelerate these processes by reducing medium viscosity and aggregate order. The findings highlight the critical role of reorientation dynamics in designing high-speed magnetic sensors, vibration isolation systems, and adaptive devices operating in dynamic magnetic environments.