Structural and Magnetic Reconstruction of Thermodynamically Stable CaMnO3 (001) Surfaces

Abstract

The relative thermodynamic stability of surface reconstructions including vacancies, adatoms and additional layers on both CaO and MnO2 terminations is calculated to predict the surface phase diagram of (2×2)R45 CaMnO3 (001) using ab initio thermodynamics. Stoichiometric and nonstoichiometric reconstructions are considered. A set of boundary conditions driven by the binary and ternary sub-phases from CaMnO3 defines its bulk stability region, enclosing the stable surface reconstructions that can be in equilibrium with the bulk. Most of the surfaces take the magnetic ordering of the bulk ground state, G-type antiferromagnetic (AFM); however, some of the MnO2-terminated surfaces are more stable when the surface layer spins flip. At 573 K, the stoichiometric CaO- and MnO2-terminated surfaces are predicted to be thermodynamically stable, as well as a CaO-terminated surface reconstruction where half the Ca are replaced by Mn. The MnO2-terminated surface reconstructions dominate the phase diagrams at high temperatures, including phases with MnO and MnO2 adatoms per surface unit cell.