Magneto-optic Faraday effect in maghemite nanoparticles/silica matrix nanocomposites prepared by the Sol-Gel method

TL;DR

This study investigates the magneto-optic Faraday effect in maghemite nanoparticles embedded in a silica matrix, prepared via the sol-gel method, demonstrating potential for magnetic field sensing applications.

Contribution

It introduces a sol-gel synthesis process for maghemite/silica nanocomposites with controlled magnetic properties and demonstrates their Faraday effect behavior for sensing purposes.

Findings

Faraday rotation is proportional to magnetization.

Samples exhibit superparamagnetic behavior at room temperature.

Preparation method yields mechanically stable, non-hysteretic samples.

Abstract

Bulk monolithic samples of {\gamma}-Fe2O3/SiO2 composites with different iron oxide/silica ratios have been prepared by the sol-gel technique. Iron oxide nanoparticles are obtained in-situ during heat treatment of samples and silica matrix consolidation. Preparation method was previously optimized to minimize the percentage of antiferromagnetic {\alpha}-Fe2O3 and parallelepipeds of roughly 2x5x12 mm3, with good mechanical stability, are obtained. RT magnetization curves show a non-hysteretic behavior. Thus, magnetization measurements have been well fitted to an expression that combines the Langevin equation with an additional linear term, indicating that some of the nanoparticles are still superparamagnetic as confirmed by X-ray diffraction and electron microscopy measurements. Zero field cooled /field cooled experiments show curves with slightly different shapes, depending on the size and shape distribution of nanoparticles for a given composition. Magneto-optical Faraday effect measurements show that the Faraday rotation is proportional to magnetization of the samples, as expected. As a demonstration of their sensing possibilities, the relative intensity of polarized light, measured at 5{\deg} from the extinction angle, was plotted versus applied magnetic field.