Atomically flat single-terminated SrTi O3 (111) surface

Jaewan Chang; Yoon Seok Park; Sang Koog Kim

doi:10.1063/1.2913005

Atomically flat single-terminated SrTi O3 (111) surface

Jaewan Chang, Yoon Seok Park, Sang Koog Kim

Research output: Contribution to journal › Article › peer-review

66 Citations (Scopus)

Abstract

The authors have reproducibly obtained an atomically well-defined SrTi O3 (111) surface by a combined chemical etching and thermal annealing process. Although thermodynamic mixed termination is preferred as a means of suppressing the surface dipole, the kinetics-driven etching process, via selective etching of Sr O3 4-, enables a single-terminated surface to be obtained. Subsequent O2 annealing of the etched surface produces a clear step-and-terrace structure. Atomically flat terraces and only one-unit-cell-high step edges are observed, signifying a single-terminated surface. This study might pave the way for constructing (111)-oriented perovskite oxide superlattices, which would be expected to demonstrate new and better physical phenomena and functionalities.

Original language	English
Article number	152910
Journal	Applied Physics Letters
Volume	92
Issue number	15
DOIs	https://doi.org/10.1063/1.2913005
Publication status	Published - 2008

Bibliographical note

Funding Information:
The authors thank C. U. Jung for valuable assistance. This work was supported by Creative Research Initiatives (ReC-SDSW) of MOST/KOSEF.

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abstract = "The authors have reproducibly obtained an atomically well-defined SrTi O3 (111) surface by a combined chemical etching and thermal annealing process. Although thermodynamic mixed termination is preferred as a means of suppressing the surface dipole, the kinetics-driven etching process, via selective etching of Sr O3 4-, enables a single-terminated surface to be obtained. Subsequent O2 annealing of the etched surface produces a clear step-and-terrace structure. Atomically flat terraces and only one-unit-cell-high step edges are observed, signifying a single-terminated surface. This study might pave the way for constructing (111)-oriented perovskite oxide superlattices, which would be expected to demonstrate new and better physical phenomena and functionalities.",

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AU - Chang, Jaewan

AU - Park, Yoon Seok

AU - Kim, Sang Koog

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PY - 2008

Y1 - 2008

N2 - The authors have reproducibly obtained an atomically well-defined SrTi O3 (111) surface by a combined chemical etching and thermal annealing process. Although thermodynamic mixed termination is preferred as a means of suppressing the surface dipole, the kinetics-driven etching process, via selective etching of Sr O3 4-, enables a single-terminated surface to be obtained. Subsequent O2 annealing of the etched surface produces a clear step-and-terrace structure. Atomically flat terraces and only one-unit-cell-high step edges are observed, signifying a single-terminated surface. This study might pave the way for constructing (111)-oriented perovskite oxide superlattices, which would be expected to demonstrate new and better physical phenomena and functionalities.

AB - The authors have reproducibly obtained an atomically well-defined SrTi O3 (111) surface by a combined chemical etching and thermal annealing process. Although thermodynamic mixed termination is preferred as a means of suppressing the surface dipole, the kinetics-driven etching process, via selective etching of Sr O3 4-, enables a single-terminated surface to be obtained. Subsequent O2 annealing of the etched surface produces a clear step-and-terrace structure. Atomically flat terraces and only one-unit-cell-high step edges are observed, signifying a single-terminated surface. This study might pave the way for constructing (111)-oriented perovskite oxide superlattices, which would be expected to demonstrate new and better physical phenomena and functionalities.

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Atomically flat single-terminated SrTi O3 (111) surface

Abstract

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