In-plane quasi-single-domain BaTiO3 via interfacial symmetry engineering

J. W. Lee; K. Eom; T. R. Paudel; B. Wang; H. Lu; H. X. Huyan; S. Lindemann; S. Ryu; H. Lee; T. H. Kim; Y. Yuan; J. A. Zorn; S. Lei; W. P. Gao; T. Tybell; V. Gopalan; X. Q. Pan; A. Gruverman; L. Q. Chen; E. Y. Tsymbal; C. B. Eom

doi:10.1038/s41467-021-26660-7

In-plane quasi-single-domain BaTiO₃ via interfacial symmetry engineering

J. W. Lee, K. Eom, T. R. Paudel, B. Wang, H. Lu, H. X. Huyan, S. Lindemann, S. Ryu, H. Lee, T. H. Kim, Y. Yuan, J. A. Zorn, S. Lei, W. P. Gao, T. Tybell, V. Gopalan, X. Q. Pan, A. Gruverman, L. Q. Chen, E. Y. TsymbalC. B. Eom

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27 Scopus citations

Abstract

The control of the in-plane domain evolution in ferroelectric thin films is not only critical to understanding ferroelectric phenomena but also to enabling functional device fabrication. However, in-plane polarized ferroelectric thin films typically exhibit complicated multi-domain states, not desirable for optoelectronic device performance. Here we report a strategy combining interfacial symmetry engineering and anisotropic strain to design single-domain, in-plane polarized ferroelectric BaTiO₃ thin films. Theoretical calculations predict the key role of the BaTiO₃/PrScO₃(110) _O substrate interfacial environment, where anisotropic strain, monoclinic distortions, and interfacial electrostatic potential stabilize a single-variant spontaneous polarization. A combination of scanning transmission electron microscopy, piezoresponse force microscopy, ferroelectric hysteresis loop measurements, and second harmonic generation measurements directly reveals the stabilization of the in-plane quasi-single-domain polarization state. This work offers design principles for engineering in-plane domains of ferroelectric oxide thin films, which is a prerequisite for high performance optoelectronic devices.

Original language	English (US)
Article number	6784
Journal	Nature communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-021-26660-7
State	Published - Dec 2021

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General Physics and Astronomy

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Lee, J. W., Eom, K., Paudel, T. R., Wang, B., Lu, H., Huyan, H. X., Lindemann, S., Ryu, S., Lee, H., Kim, T. H., Yuan, Y., Zorn, J. A., Lei, S., Gao, W. P., Tybell, T., Gopalan, V., Pan, X. Q., Gruverman, A., Chen, L. Q., ... Eom, C. B. (2021). In-plane quasi-single-domain BaTiO₃ via interfacial symmetry engineering. Nature communications, 12(1), Article 6784. https://doi.org/10.1038/s41467-021-26660-7

@article{73defed6437748f49813e3ea050027e9,

title = "In-plane quasi-single-domain BaTiO3 via interfacial symmetry engineering",

abstract = "The control of the in-plane domain evolution in ferroelectric thin films is not only critical to understanding ferroelectric phenomena but also to enabling functional device fabrication. However, in-plane polarized ferroelectric thin films typically exhibit complicated multi-domain states, not desirable for optoelectronic device performance. Here we report a strategy combining interfacial symmetry engineering and anisotropic strain to design single-domain, in-plane polarized ferroelectric BaTiO3 thin films. Theoretical calculations predict the key role of the BaTiO3/PrScO3(110) O substrate interfacial environment, where anisotropic strain, monoclinic distortions, and interfacial electrostatic potential stabilize a single-variant spontaneous polarization. A combination of scanning transmission electron microscopy, piezoresponse force microscopy, ferroelectric hysteresis loop measurements, and second harmonic generation measurements directly reveals the stabilization of the in-plane quasi-single-domain polarization state. This work offers design principles for engineering in-plane domains of ferroelectric oxide thin films, which is a prerequisite for high performance optoelectronic devices.",

author = "Lee, {J. W.} and K. Eom and Paudel, {T. R.} and B. Wang and H. Lu and Huyan, {H. X.} and S. Lindemann and S. Ryu and H. Lee and Kim, {T. H.} and Y. Yuan and Zorn, {J. A.} and S. Lei and Gao, {W. P.} and T. Tybell and V. Gopalan and Pan, {X. Q.} and A. Gruverman and Chen, {L. Q.} and Tsymbal, {E. Y.} and Eom, {C. B.}",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s).",

year = "2021",

month = dec,

doi = "10.1038/s41467-021-26660-7",

language = "English (US)",

volume = "12",

journal = "Nature communications",

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Lee, JW, Eom, K, Paudel, TR, Wang, B, Lu, H, Huyan, HX, Lindemann, S, Ryu, S, Lee, H, Kim, TH, Yuan, Y, Zorn, JA, Lei, S, Gao, WP, Tybell, T, Gopalan, V, Pan, XQ, Gruverman, A, Chen, LQ, Tsymbal, EY & Eom, CB 2021, 'In-plane quasi-single-domain BaTiO₃ via interfacial symmetry engineering', Nature communications, vol. 12, no. 1, 6784. https://doi.org/10.1038/s41467-021-26660-7

TY - JOUR

T1 - In-plane quasi-single-domain BaTiO3 via interfacial symmetry engineering

AU - Lee, J. W.

AU - Eom, K.

AU - Paudel, T. R.

AU - Wang, B.

AU - Lu, H.

AU - Huyan, H. X.

AU - Lindemann, S.

AU - Ryu, S.

AU - Lee, H.

AU - Kim, T. H.

AU - Yuan, Y.

AU - Zorn, J. A.

AU - Lei, S.

AU - Gao, W. P.

AU - Tybell, T.

AU - Gopalan, V.

AU - Pan, X. Q.

AU - Gruverman, A.

AU - Chen, L. Q.

AU - Tsymbal, E. Y.

AU - Eom, C. B.

PY - 2021/12

Y1 - 2021/12

N2 - The control of the in-plane domain evolution in ferroelectric thin films is not only critical to understanding ferroelectric phenomena but also to enabling functional device fabrication. However, in-plane polarized ferroelectric thin films typically exhibit complicated multi-domain states, not desirable for optoelectronic device performance. Here we report a strategy combining interfacial symmetry engineering and anisotropic strain to design single-domain, in-plane polarized ferroelectric BaTiO3 thin films. Theoretical calculations predict the key role of the BaTiO3/PrScO3(110) O substrate interfacial environment, where anisotropic strain, monoclinic distortions, and interfacial electrostatic potential stabilize a single-variant spontaneous polarization. A combination of scanning transmission electron microscopy, piezoresponse force microscopy, ferroelectric hysteresis loop measurements, and second harmonic generation measurements directly reveals the stabilization of the in-plane quasi-single-domain polarization state. This work offers design principles for engineering in-plane domains of ferroelectric oxide thin films, which is a prerequisite for high performance optoelectronic devices.

AB - The control of the in-plane domain evolution in ferroelectric thin films is not only critical to understanding ferroelectric phenomena but also to enabling functional device fabrication. However, in-plane polarized ferroelectric thin films typically exhibit complicated multi-domain states, not desirable for optoelectronic device performance. Here we report a strategy combining interfacial symmetry engineering and anisotropic strain to design single-domain, in-plane polarized ferroelectric BaTiO3 thin films. Theoretical calculations predict the key role of the BaTiO3/PrScO3(110) O substrate interfacial environment, where anisotropic strain, monoclinic distortions, and interfacial electrostatic potential stabilize a single-variant spontaneous polarization. A combination of scanning transmission electron microscopy, piezoresponse force microscopy, ferroelectric hysteresis loop measurements, and second harmonic generation measurements directly reveals the stabilization of the in-plane quasi-single-domain polarization state. This work offers design principles for engineering in-plane domains of ferroelectric oxide thin films, which is a prerequisite for high performance optoelectronic devices.

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SN - 2041-1723

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JO - Nature communications

JF - Nature communications

IS - 1

M1 - 6784

ER -

In-plane quasi-single-domain BaTiO₃ via interfacial symmetry engineering

Abstract

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