Slow oxidation of magnetite nanoparticles elucidates the limits of the Verwey transition

TL;DR

This study investigates how slow oxidation affects the Verwey transition in magnetite nanoparticles, revealing limits of doping and strain effects on phase transition temperatures over long aging periods.

Contribution

It provides a physical model explaining the evolution of the Verwey transition due to doping and strain, clarifying the limits of homogeneous doping in magnetite nanoparticles.

Findings

Verwey transition drops to 70 K then recovers to 95 K over time

Persistent 95 K transition corresponds to homogeneous doping limit

Inhomogeneous strains cause further suppression to 70 K

Abstract

Magnetite (Fe3O4) is of fundamental importance as the original magnetic material and also for the Verwey transition near T_V = 125 K, below which a complex lattice distortion and electron orders occur. The Verwey transition is suppressed by strain or chemical doping effects giving rise to well-documented first and second-order regimes, but the origin of the order change is unclear. Here, we show that slow oxidation of monodisperse Fe3O4 nanoparticles leads to an intriguing variation of the Verwey transition that elucidates the doping effects. Exposure to various fixed oxygen pressures at ambient temperature leads to an initial drop to TV minima as low as 70 K after 45-75 days, followed by recovery to a constant value of 95 K after 160 days that persists in all experiments for aging times up to 1070 days. A physical model based on both doping and doping-gradient effects accounts quantitatively for this evolution and demonstrates that the persistent 95 K value corresponds to the lower limit for homogenously doped magnetite and hence for the first order regime. In comparison, further suppression down to 70 K results from inhomogeneous strains that characterize the second-order region. This work demonstrates that slow reactions of nanoparticles can give exquisite control and separation of homogenous and inhomogeneous doping or strain effects on an nm scale and offers opportunities for similar insights into complex electronic and magnetic phase transitions in other materials.