Laser spectroscopy of finite size and covering effects in magnetite nanoparticles

TL;DR

This study investigates how the size and surface states of magnetite nanoparticles influence their magnetic properties, using experimental techniques and Monte Carlo simulations to reveal size-dependent shifts in Curie temperature and magnetic moments.

Contribution

It introduces real-time DLS control during nanoparticle separation and combines experimental data with theoretical modeling to analyze size and surface effects on magnetite NPs.

Findings

Size affects Curie temperature and magnetic properties.

Surface spin states significantly influence magnetic behavior.

Both size and surface conditions determine magnetic moments.

Abstract

The experiments on the impact of the size of magnetite clusters on various magnetic properties (magnetic moment, Curie temperature, blocking temperature etc.) have been carried out. The methods of magnetic separation, centrifuging of water suspensions of biocompatible iron oxide nanoparticles (NPs) allow producing fractions with diameter of nanoparticles in the range of 4{\div}22 nm. The size of NPs are controlled by the methods of dynamic light scattering (DLS), transmission electron microscopy (TEM) and atomic force microscopy (AFM). For the first time the DLS method is applied in real time to control the size during the process of the separation of the NPs in aqueous suspensions. The changes of the size of NPs cause a shift in the Curie temperature and in the changes in the specific magnetic properties of the iron NPs. The experimental data is interpreted on the basis of Monte Carlo simulations for the classical Heisenberg model with different bulk and surface magnetic moments. It is demonstrated experimentally and by theoretical modeling that magnetic properties of magnetite NPs are determined not only by their sizes, but also by the their surface spin states, while both growing and falling dependences of the magnetic moment (per Fe3O4 formula unit) being possible, depending on the number of magnetic atoms in the nanoparticle. Both NPs clean and covered with a bioresorbable layer clusters have been investigated.