%0 Journal Article %1 noauthororeditor %A Schütz, P. %A Kamp, M. %A Di Sante, D. %A Lubk, A. %A Büchner, B. %A Sangiovanni, G. %A Sing, M. %A Claessen, R. %D 2020 %J Appl. Phys. Lett. %K a d %N 20 %P 201601 %T Electronic structure of epitaxial perovskite films in the two-dimensional limit: Role of the surface termination %U https://aip.scitation.org/doi/10.1063/5.0002985 %V 116 %X An often-overlooked property of transition metal oxide thin films is their microscopic surface structure and its effect on the electronic properties in the ultrathin limit. Contrary to the expected conservation of the perovskite stacking order in the (001) direction, heteroepitaxially grown SrIrO3 films on TiO2-terminated SrTiO3 are found to exhibit a terminating SrO surface layer. The proposed mechanism for the self-organized conversion involves the adsorption of excess oxygen ions at the apical sites of the $IrO_2$-terminated surface and the subsequent decomposition of the IrO6 octahedra into gaseous molecular $IrO_3$ and the remaining SrO-terminated surface. Whereas the ab initio calculated electronic structure of SrO-terminated $SrIrO_3$ in the monolayer limit exhibits a striking similarity to bulk $Sr_2IrO_4$, the broken octahedral symmetry at the $IrO_2$-terminated surface would mix the otherwise crystal field split eg and t2g states, resulting in distinctly different low-energy electronic states.

@article{noauthororeditor, abstract = {An often-overlooked property of transition metal oxide thin films is their microscopic surface structure and its effect on the electronic properties in the ultrathin limit. Contrary to the expected conservation of the perovskite stacking order in the (001) direction, heteroepitaxially grown SrIrO3 films on TiO2-terminated SrTiO3 are found to exhibit a terminating SrO surface layer. The proposed mechanism for the self-organized conversion involves the adsorption of excess oxygen ions at the apical sites of the $IrO_2$-terminated surface and the subsequent decomposition of the IrO6 octahedra into gaseous molecular $IrO_3$ and the remaining SrO-terminated surface. Whereas the ab initio calculated electronic structure of SrO-terminated $SrIrO_3$ in the monolayer limit exhibits a striking similarity to bulk $Sr_2IrO_4$, the broken octahedral symmetry at the $IrO_2$-terminated surface would mix the otherwise crystal field split eg and t2g states, resulting in distinctly different low-energy electronic states.}, added-at = {2021-03-01T11:57:24.000+0100}, author = {Schütz, P. and Kamp, M. and Di Sante, D. and Lubk, A. and Büchner, B. and Sangiovanni, G. and Sing, M. and Claessen, R.}, biburl = {https://www.bibsonomy.org/bibtex/2ea7050488eea1bfc21e9ed026f7da2ba/ctqmat}, day = 18, description = {Electronic structure of epitaxial perovskite films in the two-dimensional limit: Role of the surface termination: Applied Physics Letters: Vol 116, No 20}, interhash = {5aafafe9557cd5c85dadc6ba2ebbe071}, intrahash = {ea7050488eea1bfc21e9ed026f7da2ba}, journal = {Appl. Phys. Lett.}, keywords = {a d}, month = {05}, number = 20, pages = 201601, timestamp = {2023-10-16T11:25:58.000+0200}, title = {Electronic structure of epitaxial perovskite films in the two-dimensional limit: Role of the surface termination}, url = {https://aip.scitation.org/doi/10.1063/5.0002985}, volume = 116, year = 2020 }