Printable Nanocomposites with Superparamagnetic Maghemite (γ-Fe2O3) Particles for Microinductor-core Applications

Abstract

We here present printable and castable magnetic nanocomposites containing superparamagnetic 113 nm γ-Fe2O3 particles in an insulating poly-vinyl alcohol polymer matrix. The nanocomposites feature well-dispersed particles with volume fractions between 10 and 45 \%, as confirmed by small-angle neutron scattering. The magnetic volume susceptibility is as high as 17, together with negligible hysteresis at low frequency, and constant AC-response up to the high-kHz range. Measured hysteresis curves at 100-900 kHz with up to 110 mT induced B-fields in the nanocomposite show that power losses depend on B-field squared, and frequency to the power of 1-1.3. The only loss mechanism in the nanocomposite is hysteresis losses at >100 kHz frequencies, where the largest particles in the 113 nm distribution transition from the superparamagnetic to blocked regime. To mitigate the resulting hysteresis losses (up 102-105 kW/m3) a more narrow particle size distribution could be used for future materials. The presented material is eddy current-free and easily integrated into micro-fabrication protocols, as we demonstrate by fabrication of 3-turn print circuit board based inductors with cast/manual printed nanocomposite inductor cores, on which induction has been measured up to 100 MHz.