Engineering the oxygen coordination in digital superlattices

Engineering the oxygen coordination in digital superlattices

The oxygen sublattice in complex oxides is typically composed of corner-shared polyhedra, with transition metals at their centers. The electronic and chemical properties of the oxide depend on the type and geometric arrangement of these polyhedra, which can be controlled through epitaxial synthesis....

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Main Authors: Seyoung Cook, Tassie K. Andersen, Hawoong Hong, Richard A. Rosenberg, Laurence D. Marks, Dillon D. Fong
Format: Article
Language:English
Published: AIP Publishing LLC 2017-12-01
Series:APL Materials
Online Access:http://dx.doi.org/10.1063/1.5007663
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spelling doaj-46cc5a6943784edb99ebe7987fba62dc2020-11-25T01:33:12ZengAIP Publishing LLCAPL Materials2166-532X2017-12-01512126101126101-810.1063/1.5007663003712APMEngineering the oxygen coordination in digital superlatticesSeyoung Cook0Tassie K. Andersen1Hawoong Hong2Richard A. Rosenberg3Laurence D. Marks4Dillon D. Fong5Materials Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USAMaterials Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USAX-Ray Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USAX-Ray Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USADepartment of Materials Science, Northwestern University, Evanston, Illinois 60202, USAMaterials Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USAThe oxygen sublattice in complex oxides is typically composed of corner-shared polyhedra, with transition metals at their centers. The electronic and chemical properties of the oxide depend on the type and geometric arrangement of these polyhedra, which can be controlled through epitaxial synthesis. Here, we use oxide molecular beam epitaxy to create SrCoOx:SrTiO3 superlattices with tunable oxygen coordination environments and sublattice geometries. Using synchrotron X-ray scattering in combination with soft X-ray spectroscopy, we find that the chemical state of Co can be varied with the polyhedral arrangement, with higher Co oxidation states increasing the valence band maximum. This work demonstrates a new strategy for engineering unique electronic structures in the transition metal oxides using short-period superlattices.http://dx.doi.org/10.1063/1.5007663
collection DOAJ
language English
format Article
sources DOAJ
author Seyoung Cook
Tassie K. Andersen
Hawoong Hong
Richard A. Rosenberg
Laurence D. Marks
Dillon D. Fong
spellingShingle Seyoung Cook
Tassie K. Andersen
Hawoong Hong
Richard A. Rosenberg
Laurence D. Marks
Dillon D. Fong
Engineering the oxygen coordination in digital superlattices
APL Materials
author_facet Seyoung Cook
Tassie K. Andersen
Hawoong Hong
Richard A. Rosenberg
Laurence D. Marks
Dillon D. Fong
author_sort Seyoung Cook
title Engineering the oxygen coordination in digital superlattices
title_short Engineering the oxygen coordination in digital superlattices
title_full Engineering the oxygen coordination in digital superlattices
title_fullStr Engineering the oxygen coordination in digital superlattices
title_full_unstemmed Engineering the oxygen coordination in digital superlattices
title_sort engineering the oxygen coordination in digital superlattices
publisher AIP Publishing LLC
series APL Materials
issn 2166-532X
publishDate 2017-12-01
description The oxygen sublattice in complex oxides is typically composed of corner-shared polyhedra, with transition metals at their centers. The electronic and chemical properties of the oxide depend on the type and geometric arrangement of these polyhedra, which can be controlled through epitaxial synthesis. Here, we use oxide molecular beam epitaxy to create SrCoOx:SrTiO3 superlattices with tunable oxygen coordination environments and sublattice geometries. Using synchrotron X-ray scattering in combination with soft X-ray spectroscopy, we find that the chemical state of Co can be varied with the polyhedral arrangement, with higher Co oxidation states increasing the valence band maximum. This work demonstrates a new strategy for engineering unique electronic structures in the transition metal oxides using short-period superlattices.
url http://dx.doi.org/10.1063/1.5007663
work_keys_str_mv AT seyoungcook engineeringtheoxygencoordinationindigitalsuperlattices
AT tassiekandersen engineeringtheoxygencoordinationindigitalsuperlattices
AT hawoonghong engineeringtheoxygencoordinationindigitalsuperlattices
AT richardarosenberg engineeringtheoxygencoordinationindigitalsuperlattices
AT laurencedmarks engineeringtheoxygencoordinationindigitalsuperlattices
AT dillondfong engineeringtheoxygencoordinationindigitalsuperlattices
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