Measurement of the BaTiO3 domain structure by using ultrahigh-vacuum atomic force microscopy (UHV-AFM)

Shigeru Kaku; Satoshi Miyauchi; Yukio Watanabe

doi:10.3938/jkps.55.799

Measurement of the BaTiO₃ domain structure by using ultrahigh-vacuum atomic force microscopy (UHV-AFM)

Shigeru Kaku, Satoshi Miyauchi, Yukio Watanabe

Condensed Matter Physics

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

10 Citations (Scopus)

Abstract

We report the nanoscopic properties of the clean, free surface of a BaTiO₃ single crystal in an ultra-high vacuum. Atomic force microscopy, piezoelectric force microscopy and Kelvin force microscopy measurements show that the potential difference between upward and downward 180° domain is approx 100 mV. This value is 100 times smaller than the value estimated by using the standard 180° domain theory. Furthermore, our experiments show that this result cannot be explained only by the conventional explanations (that is, a decrease in the depolarization field by closure domains, the compensation of polarization bound charge by contamination or by oxygen excess and deficiency or ion transport). The results suggest a possibility that an intrinsic electrostatic shielding mechanism exists in the ferroelectrics and is essential for 180° domains.

Original language	English
Pages (from-to)	799-802
Number of pages	4
Journal	Journal of the Korean Physical Society
Volume	55
Issue number	2 PART 1
DOIs	https://doi.org/10.3938/jkps.55.799
Publication status	Published - Aug 2009

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)

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abstract = "We report the nanoscopic properties of the clean, free surface of a BaTiO3 single crystal in an ultra-high vacuum. Atomic force microscopy, piezoelectric force microscopy and Kelvin force microscopy measurements show that the potential difference between upward and downward 180° domain is approx 100 mV. This value is 100 times smaller than the value estimated by using the standard 180° domain theory. Furthermore, our experiments show that this result cannot be explained only by the conventional explanations (that is, a decrease in the depolarization field by closure domains, the compensation of polarization bound charge by contamination or by oxygen excess and deficiency or ion transport). The results suggest a possibility that an intrinsic electrostatic shielding mechanism exists in the ferroelectrics and is essential for 180° domains.",

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N2 - We report the nanoscopic properties of the clean, free surface of a BaTiO3 single crystal in an ultra-high vacuum. Atomic force microscopy, piezoelectric force microscopy and Kelvin force microscopy measurements show that the potential difference between upward and downward 180° domain is approx 100 mV. This value is 100 times smaller than the value estimated by using the standard 180° domain theory. Furthermore, our experiments show that this result cannot be explained only by the conventional explanations (that is, a decrease in the depolarization field by closure domains, the compensation of polarization bound charge by contamination or by oxygen excess and deficiency or ion transport). The results suggest a possibility that an intrinsic electrostatic shielding mechanism exists in the ferroelectrics and is essential for 180° domains.

AB - We report the nanoscopic properties of the clean, free surface of a BaTiO3 single crystal in an ultra-high vacuum. Atomic force microscopy, piezoelectric force microscopy and Kelvin force microscopy measurements show that the potential difference between upward and downward 180° domain is approx 100 mV. This value is 100 times smaller than the value estimated by using the standard 180° domain theory. Furthermore, our experiments show that this result cannot be explained only by the conventional explanations (that is, a decrease in the depolarization field by closure domains, the compensation of polarization bound charge by contamination or by oxygen excess and deficiency or ion transport). The results suggest a possibility that an intrinsic electrostatic shielding mechanism exists in the ferroelectrics and is essential for 180° domains.

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Measurement of the BaTiO₃ domain structure by using ultrahigh-vacuum atomic force microscopy (UHV-AFM)

Abstract

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