Antiphase domain boundaries at the Fe 3O 4(001) surface

Authors

Gareth S. Parkinson, Technische Universität Wien
Thomas A. Manz, Georgia Institute of Technology
Zbyněk Novotný, Technische Universität Wien
Phillip T. Sprunger, Louisiana State University
Richard L. Kurtz, Louisiana State University
Michael Schmid, Technische Universität Wien
David S. Sholl, Georgia Institute of Technology
Ulrike Diebold, Technische Universität Wien

Document Type

Article

Publication Date

5-24-2012

Abstract

Antiphase domain boundaries (APDBs) in the (√2×√2) R45 ° reconstruction of the Fe 3O 4(001) surface were investigated using scanning tunneling microscopy (STM) and density functional theory [(DFT) + U] calculations. The equilibrium structure of the APDBs is interpreted in terms of the distorted B-layer model for the (√2×√2)R45 ° reconstruction in which a lattice distortion couples to charge order in the subsurface layers. The APDBs are observed after prolonged annealing at 700°C, indicating that they are extremely stable. DFT + U calculations reveal that the APDB structure is linked to a disruption in the subsurface charge-order pattern, leading to an enrichment of Fe2 + cations at the APDB. Simulated STM images reproduce the appearance of the APDBs in the experimental data and reveal that they are preferential adsorption sites for hydrogen atoms. © 2012 American Physical Society.

Publication Source (Journal or Book title)

Physical Review B - Condensed Matter and Materials Physics

Recommended Citation

Parkinson, G., Manz, T., Novotný, Z., Sprunger, P., Kurtz, R., Schmid, M., Sholl, D., & Diebold, U. (2012). Antiphase domain boundaries at the Fe 3O 4(001) surface. Physical Review B - Condensed Matter and Materials Physics, 85 (19) https://doi.org/10.1103/PhysRevB.85.195450