Atomistic simulations of surface reactions in ultra-high-temperature ceramics: O2, H2O and CO adsorption and dissociation on ZrB2 (0001) surfaces

TL;DR

This study uses density functional theory to analyze how O2, H2O, and CO interact with ZrB2 surfaces, revealing that O2 dissociation dominates surface reactivity and can cause surface reconstruction, informing material stability in aerospace environments.

Contribution

The paper provides the first detailed computational analysis of surface reactions of ZrB2 with key molecules, highlighting the dominant role of O2 dissociation and surface reconstruction mechanisms.

Findings

O2 dissociative adsorption dominates ZrB2 surface reactivity.

H2O and CO dissociate weakly, especially on B-terminated surfaces.

O2 and H2O reactions can induce strong surface reconstruction.

Abstract

Understanding surface reactivity is crucial in many fields, going from heterogeneous catalysis to materials oxidation and corrosion. In order to decipher the surface reactions of ZrB2 exposed to the harsh environment of aerospace components, the chemical activity of both Zr- and B-surfaces is predicted and compared by using density functional theory and nudged elastic band methods. In particular the adsorption, dissociation and diffusion of O2, CO and H2O are extensively examined through the calculation of surface adsorption energies and reaction pathways. We find the dissociative adsorption of O2 dominating the reactivity of ZrB2 surfaces, while the dissociation of H2O and CO is weakly active on Zr-surfaces, and even less activated on B-terminated ones. Importantly, we discover that the reaction of O2 and H2O can trigger strong surface reconstruction at B-surfaces. Our work thus provides significant insights into the diverse adsorption and reaction mechanisms of ZrB2 surfaces.