Predicting the Structural, Electronic and Magnetic Properties of Few Atomic-layer Polar Perovskite

Abstract

Density functional theory (DFT) calculations are performed to predict the structural, electronic and magnetic properties of electrically neutral or charged few-atomic-layer (AL) oxides whose parent systems are based on polar perovskite KTaO3. Their properties vary greatly with the number of ALs (nAL) and the stoichiometric ratio. In the few-AL limit (nAL≤slant 14), the even AL (EL) systems with chemical formula (KTaO3)n are semiconductors, while the odd AL (OL) systems with formula (Kn+1TanO3n+1 or KnTan+1O3n+2) are half-metal except for the unique KTa2O5 case which is a semiconductor due to the large Peierls distortions. After reaching certain critical thickness (nAL>14), the EL systems show ferromagnetic surface states, while ferromagnetism disappears in the OL systems. These predictions from fundamental complexity of polar perovskite when approaching the two-dimensional (2D) limit may be helpful for interpreting experimental observations later.