Atom-scale oxidation mechanism of nanoparticles helps develop anti-corrosion materials (Nanowerk News) The research group led by Prof. BAO Xinhe from Dalian Institute of Chemical Physics, Chinese Academy of Sciences discovered that oxide nanostructures (NSs) with a diameter below 3 nm could exhibit an oxidation resistance much more superior than larger NSs. By investigating the oxidation mechanism at the atomic level, the team proposed, for the first time, a "dynamic size effect", that determines the stability of supported nanoparticles.

These findings were published in the latest issue of ("Enhanced oxidation resistance of active nanostructures via dynamic size effect"). This study not only brings the atomic understanding of the dynamic remodeling mechanism of nanocatalyst under the atmosphere, but also provides a new interface control for the development of anti-corrosion and anti-oxidation nano-protective coating.

This is a schematic illustration of the dynamic size effect in enhancing the oxidation resistance of active FeO NSs. (Image: YANG Fan)

A major challenge limiting the practical applications of nanomaterials is that the activities of NSs increase with reduced size, often sacrificing their stability in the chemical environment. Under oxidative conditions, NSs with smaller sizes and higher defect densities are commonly expected to oxidize more easily, since high-concentration defects can facilitate oxidation by enhancing the reactivity with O2 and providing a fast channel for oxygen incorporation.

Yet, several nanocrystalline materials were also reported previously to exhibit improved oxidation resistance with respect to bulk materials and have been applied as anti-corrosion coatings. The lack of general consensus on the oxidation resistance of oxide NSs has been attributed to the limited understanding on the underlying mechanism of oxidation. Particularly, the oxidation kinetics of NSs with diameters below 5 nm have rarely been studied.

BAO's team and Prof. YANG Fan thus constructed FeO NSs with different sizes on Pt (111) and studied their oxidation kinetics using high resolution scanning tunneling microscopy (STM) and density-functional theory (DFT) calculations. Reducing the size of active FeO NSs was found to increase drastically their oxidation resistance and a maximum oxidation resistance is found for FeO NSs with dimensions below 3.2 nm. The team found the enhanced oxidation resistance originates from the size-dependent structural dynamics of FeO NSs in O2.

Specifically, the study shows that FeO NSs with a size below 3.2 nm could undergo a facile and complete reconstruction, when O2 dissociates at the coordinatively unsaturated ferrous centers at the edges of FeO NSs. Accompanying the reconstruction, the dissociated oxygen atoms are stabilized at the edges of FeO NSs and could not penetrate into the interface FeO and Pt, thereby inhibiting the further oxidation of FeO NSs. FeO NSs with dimensions above 3.2 nm are easier to be oxidized, because of their inability to complete the reconstruction, accompanied by the formation of surface dislocations.