Microscopic understanding of the orbital splitting and its tuning at oxide interfaces
arXiv:1205.4001 · doi:10.1209/0295-5075/99/37011
Abstract
By means of a Wannier projection within the framework of density functional theory, we are able to identify the modified c-axis hopping and the energy mismatch between the cation bands as the main source of the $t_{2g}$ splitting around the $Î$ point for oxide heterostructures, excluding previously proposed mechanisms such as Jahn-Teller distortions or electric field asymmetries. Interfacing LaAlO$_3$, LaVO$_3$, SrVO$_3$ and SrNbO$_3$ with SrTiO$_3$ we show how to tune this orbital splitting, designing heterostructures with more $d_{xy}$ electrons at the interface. Such an "orbital engineering" is the key for controlling the physical properties at the interface of oxide heterostructures.
4.5 pages, 4 figures, submitted on May 9. 2012 to Physical Review. PDF Supplementary material containing tables of hopping and energy levels for the different heterostructures