Vacancy-induced magnetic states in TiO2 surfaces

We present a combined experimental and theoretical study of surface-related magnetic states in TiO2. Our experiments on nano-sized thin films of pure TiO(2 )have suggested that the observed room-temperature magnetism originates from defects, in particular, from the surface of thin films as well as from point defects, such as oxygen vacancies located mainly at the surface. Clarifying this phenomenon is very important for harnessing magnetic properties of pristine TiO(2 )films in future spintronic applications but a detailed experimental investigation is very demanding. Therefore, quantum-mechanical density functional theory calculations were performed for (i) bulk anatase TiO2, (ii) bulk-like TiO2-terminated vacancy-free (001) surfaces, (iii) vacancy-containing TiO-terminated (001) surfaces, (iv) TiO0.75-terminated (001) surfaces with additional 25% surface oxygen vacancies, as well as (v) oxygen-terminated (001)-surfaces. Our fixed-spin-moment calculations identified both the bulk and the bulk-like terminated vacancy-free TiO2-terminated (001) surfaces as non-magnetic. In contrast, oxygen vacancies in the case of TiO-terminated and TiO0.75-terminated (001) surfaces lead to ferromagnetic and rather complex ferrimagnetic states, respectively. The spin-polarized atoms are the Ti atoms (due to the d-states) located in the surface and sub-surface atomic planes. Last, the O-terminated surfaces are also magnetic due to the surface and sub-surface oxygen atoms and sub-surface Ti atoms (but their surface energy is high).

Automated summary

We have conducted a combined experimental and theoretical study on the surface-related magnetic states in TiO2. The room-temperature magnetism observed in pure TiO2 thin films is found to originate from defects, particularly from the surface of thin films and oxygen vacancies mainly located at the surface. Detailed experimental investigations are demanding, hence we performed quantum-mechanical density functional theory calculations to clarify this phenomenon. Our calculations identified non-magnetic behavior in bulk anatase TiO2 and bulk-like TiO2-terminated (001) surfaces without vacancies. However, oxygen vacancies in TiO-terminated and TiO0.75-terminated (001) surfaces led to ferromagnetic and rather complex ferrimagnetic states, respectively. Spin-polarized atoms were found in the surface and sub-surface atomic planes, particularly the Ti atoms due to the d-states. The O-terminated surfaces also exhibited magnetism, but with high surface energy.