Ultrahigh dielectric permittivity in oxide ceramics by hydrogenation

Nguyen Xuan Duong; Ji Soo Jang; Min Hyoung Jung; Jong Seong Bae; Chang Won Ahn; Jong Sung Jin; Kyuwook Ihm; Gyehyeon Kim; So Yeon Lim; Jongmin Lee; Dang Duc Dung; Soonil Lee; Young Min Kim; Sanghan Lee; Sang Mo Yang; Changhee Sohn; Ill Won Kim; Hu Young Jeong; Seung Hyub Baek; Tae Heon Kim

doi:10.1126/sciadv.add8328

Ultrahigh dielectric permittivity in oxide ceramics by hydrogenation

Nguyen Xuan Duong
, Ji Soo Jang
, Min Hyoung Jung
, Jong Seong Bae
, Chang Won Ahn
, Jong Sung Jin
, Kyuwook Ihm
, Gyehyeon Kim
, So Yeon Lim
, Jongmin Lee
, Dang Duc Dung
, Soonil Lee
, Young Min Kim
, Sanghan Lee
, Sang Mo Yang
, Changhee Sohn
, Ill Won Kim
, Hu Young Jeong
, Seung Hyub Baek
, Tae Heon Kim

Department of Energy

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

21 Scopus citations

Abstract

Boosting dielectric permittivity representing electrical polarizability of dielectric materials has been considered a keystone for achieving scientific breakthroughs as well as technological advances in various multifunctional devices. Here, we demonstrate sizable enhancements of low-frequency dielectric responses in oxygen-deficient oxide ceramics through specific treatments under humid environments. Ultrahigh dielectric permittivity (~5.2 × 106 at 1 Hz) is achieved by hydrogenation, when Ni-substituted BaTiO3 ceramics are exposed to high humidity. Intriguingly, thermal annealing can restore the dielectric on-state (exhibiting huge polarizability in the treated ceramics) to the initial dielectric off-state (displaying low polarizability of ~103 in the pristine ceramics after sintering). The conversion between these two dielectric states via the ambient environment-mediated treatments and the successive application of external stimuli allows us to realize reversible control of dielectric relaxation characteristics in oxide ceramics. Conceptually, our findings are of practical interest for applications to highly efficient dielectric-based humidity sensors.

Original language	English
Article number	eadd8328
Journal	Science Advances
Volume	9
Issue number	8
DOIs	https://doi.org/10.1126/sciadv.add8328
State	Published - Feb 2023

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Duong, N. X., Jang, J. S., Jung, M. H., Bae, J. S., Ahn, C. W., Jin, J. S., Ihm, K., Kim, G., Lim, S. Y., Lee, J., Dung, D. D., Lee, S., Kim, Y. M., Lee, S., Yang, S. M., Sohn, C., Kim, I. W., Jeong, H. Y., Baek, S. H., & Kim, T. H. (2023). Ultrahigh dielectric permittivity in oxide ceramics by hydrogenation. Science Advances, 9(8), Article eadd8328. https://doi.org/10.1126/sciadv.add8328

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title = "Ultrahigh dielectric permittivity in oxide ceramics by hydrogenation",

abstract = "Boosting dielectric permittivity representing electrical polarizability of dielectric materials has been considered a keystone for achieving scientific breakthroughs as well as technological advances in various multifunctional devices. Here, we demonstrate sizable enhancements of low-frequency dielectric responses in oxygen-deficient oxide ceramics through specific treatments under humid environments. Ultrahigh dielectric permittivity (\textasciitilde{}5.2 × 106 at 1 Hz) is achieved by hydrogenation, when Ni-substituted BaTiO3 ceramics are exposed to high humidity. Intriguingly, thermal annealing can restore the dielectric on-state (exhibiting huge polarizability in the treated ceramics) to the initial dielectric off-state (displaying low polarizability of \textasciitilde{}103 in the pristine ceramics after sintering). The conversion between these two dielectric states via the ambient environment-mediated treatments and the successive application of external stimuli allows us to realize reversible control of dielectric relaxation characteristics in oxide ceramics. Conceptually, our findings are of practical interest for applications to highly efficient dielectric-based humidity sensors.",

author = "Duong, \{Nguyen Xuan\} and Jang, \{Ji Soo\} and Jung, \{Min Hyoung\} and Bae, \{Jong Seong\} and Ahn, \{Chang Won\} and Jin, \{Jong Sung\} and Kyuwook Ihm and Gyehyeon Kim and Lim, \{So Yeon\} and Jongmin Lee and Dung, \{Dang Duc\} and Soonil Lee and Kim, \{Young Min\} and Sanghan Lee and Yang, \{Sang Mo\} and Changhee Sohn and Kim, \{Ill Won\} and Jeong, \{Hu Young\} and Baek, \{Seung Hyub\} and Kim, \{Tae Heon\}",

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doi = "10.1126/sciadv.add8328",

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AU - Duong, Nguyen Xuan

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AU - Ahn, Chang Won

AU - Jin, Jong Sung

AU - Ihm, Kyuwook

AU - Kim, Gyehyeon

AU - Lim, So Yeon

AU - Lee, Jongmin

AU - Dung, Dang Duc

AU - Lee, Soonil

AU - Kim, Young Min

AU - Lee, Sanghan

AU - Yang, Sang Mo

AU - Sohn, Changhee

AU - Kim, Ill Won

AU - Jeong, Hu Young

AU - Baek, Seung Hyub

AU - Kim, Tae Heon

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N2 - Boosting dielectric permittivity representing electrical polarizability of dielectric materials has been considered a keystone for achieving scientific breakthroughs as well as technological advances in various multifunctional devices. Here, we demonstrate sizable enhancements of low-frequency dielectric responses in oxygen-deficient oxide ceramics through specific treatments under humid environments. Ultrahigh dielectric permittivity (~5.2 × 106 at 1 Hz) is achieved by hydrogenation, when Ni-substituted BaTiO3 ceramics are exposed to high humidity. Intriguingly, thermal annealing can restore the dielectric on-state (exhibiting huge polarizability in the treated ceramics) to the initial dielectric off-state (displaying low polarizability of ~103 in the pristine ceramics after sintering). The conversion between these two dielectric states via the ambient environment-mediated treatments and the successive application of external stimuli allows us to realize reversible control of dielectric relaxation characteristics in oxide ceramics. Conceptually, our findings are of practical interest for applications to highly efficient dielectric-based humidity sensors.

AB - Boosting dielectric permittivity representing electrical polarizability of dielectric materials has been considered a keystone for achieving scientific breakthroughs as well as technological advances in various multifunctional devices. Here, we demonstrate sizable enhancements of low-frequency dielectric responses in oxygen-deficient oxide ceramics through specific treatments under humid environments. Ultrahigh dielectric permittivity (~5.2 × 106 at 1 Hz) is achieved by hydrogenation, when Ni-substituted BaTiO3 ceramics are exposed to high humidity. Intriguingly, thermal annealing can restore the dielectric on-state (exhibiting huge polarizability in the treated ceramics) to the initial dielectric off-state (displaying low polarizability of ~103 in the pristine ceramics after sintering). The conversion between these two dielectric states via the ambient environment-mediated treatments and the successive application of external stimuli allows us to realize reversible control of dielectric relaxation characteristics in oxide ceramics. Conceptually, our findings are of practical interest for applications to highly efficient dielectric-based humidity sensors.

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JO - Science Advances

JF - Science Advances

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Ultrahigh dielectric permittivity in oxide ceramics by hydrogenation

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