First principles insights into stability of defected MXenes in water

Two-dimensional transition metal carbides and nitrides, known as MXenes, have demonstrated remarkable performance in electrochemical energy storage and various other applications. Despite their potential, MXenes exhibit instability in aqueous solutions, and the role of defects in their aqueous stability is unclear. In this study, we report on the interfacial chemistry between water and defected Ti3C2O2 MXene at room temperature using first principles molecular dynamics simulations. We investigate how defects such as O vacancy, Ti vacancy, F terminal groups, and Ti-O vacancy pair influence the chemical interaction of water molecules with the basal plane of Ti3C2O2. Our results show that water molecules can repair the surface O vacancies, by dissociating to hydroxide and hydronium. On the other hand, F terminal groups cannot effectively block water chemisorption on the surface Ti, while Ti vacancies behave as a spectator species on the surface with respect to interaction with water. Ti3C2O2 with a Ti-O vacancy pair is found to behave like Ti3C2O2 with an O vacancy where a water molecule dissociates and refills the vacancy. These findings enrich our understanding of water interaction with defects on the MXene surfaces. First principles molecular dynamics reveals how different types of defects on the Ti3C2Tx MXene surface influence its interaction with water.

Automated summary

This study investigated the interfacial chemistry between water and defected Ti3C2O2 MXene using first principles molecular dynamics simulations. The results showed that water molecules can repair the surface O vacancies by dissociating to hydroxide and hydronium. F terminal groups cannot effectively block water chemisorption, while Ti vacancies behave as a spectator species with respect to interaction with water.