Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO2

Mengqi Jiang; Wanbiao Hu; Lilit Jacob; Qingbo Sun; Nicholas Cox; Doukyun Kim; Ye Tian; Luyang Zhao; Yang Liu; Li Jin; Zhuo Xu; Peng Liu; Gang Zhao; Jian Wang; Šarū Nas Svirskas; Jū Ras Banys; Chul Hong Park; Terry J. Frankcombe; Xiaoyong Wei; Yun Liu

doi:10.1021/acsami.1c09632

Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO₂

Mengqi Jiang, Wanbiao Hu, Lilit Jacob, Qingbo Sun, Nicholas Cox, Doukyun Kim, Ye Tian, Luyang Zhao, Yang Liu, Li Jin, Zhuo Xu, Peng Liu, Gang Zhao, Jian Wang, Šarū Nas Svirskas, Jū Ras Banys, Chul Hong Park, Terry J. Frankcombe^*, Xiaoyong Wei^*, Yun Liu^*

^*Corresponding author for this work

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

15 Citations (Scopus)

Abstract

High permittivity materials for a gigahertz (GHz) communication technology have been actively sought for some time. Unfortunately, in most materials, the dielectric constant starts to drop as frequencies increase through the megahertz (MHz) range. In this work, we report a large dielectric constant of ∼800 observed in defect-mediated rutile SnO2 ceramics, which is nearly frequency and temperature independent over the frequency range of 1 mHz to 35 GHz and temperature range of 50-450 K. Experimental and theoretical investigations demonstrate that the origin of the high dielectric constant can be attributed to the formation of locally well-defined Zn2+-Nb4+ defect clusters, which create hole-pinned defect dipoles. We believe that this work provides a promising strategy to advance dipole polarization theory and opens up a direction for the design and development of high frequency, broadband dielectric materials for use in future communication technology.

Original language	English
Pages (from-to)	54124-54132
Number of pages	9
Journal	ACS applied materials & interfaces
Volume	13
Issue number	45
DOIs	https://doi.org/10.1021/acsami.1c09632
Publication status	Published - 17 Nov 2021

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Jiang, M., Hu, W., Jacob, L., Sun, Q., Cox, N., Kim, D., Tian, Y., Zhao, L., Liu, Y., Jin, L., Xu, Z., Liu, P., Zhao, G., Wang, J., Svirskas, Š. N., Banys, J. R., Park, C. H., Frankcombe, T. J., Wei, X., & Liu, Y. (2021). Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO₂. ACS applied materials & interfaces, 13(45), 54124-54132. https://doi.org/10.1021/acsami.1c09632

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title = "Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO2",

abstract = "High permittivity materials for a gigahertz (GHz) communication technology have been actively sought for some time. Unfortunately, in most materials, the dielectric constant starts to drop as frequencies increase through the megahertz (MHz) range. In this work, we report a large dielectric constant of ∼800 observed in defect-mediated rutile SnO2 ceramics, which is nearly frequency and temperature independent over the frequency range of 1 mHz to 35 GHz and temperature range of 50-450 K. Experimental and theoretical investigations demonstrate that the origin of the high dielectric constant can be attributed to the formation of locally well-defined Zn2+-Nb4+ defect clusters, which create hole-pinned defect dipoles. We believe that this work provides a promising strategy to advance dipole polarization theory and opens up a direction for the design and development of high frequency, broadband dielectric materials for use in future communication technology.",

keywords = "SnO, codoping, defect clusters, gigahertz, high-frequency dielectric property",

author = "Mengqi Jiang and Wanbiao Hu and Lilit Jacob and Qingbo Sun and Nicholas Cox and Doukyun Kim and Ye Tian and Luyang Zhao and Yang Liu and Li Jin and Zhuo Xu and Peng Liu and Gang Zhao and Jian Wang and Svirskas, {{\v S}arū Nas} and Banys, {Jū Ras} and Park, {Chul Hong} and Frankcombe, {Terry J.} and Xiaoyong Wei and Yun Liu",

note = "Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",

year = "2021",

month = nov,

day = "17",

doi = "10.1021/acsami.1c09632",

language = "English",

volume = "13",

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journal = "ACS applied materials & interfaces",

issn = "1944-8244",

publisher = "American Chemical Society",

number = "45",

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Jiang, M, Hu, W, Jacob, L, Sun, Q , Cox, N, Kim, D, Tian, Y, Zhao, L, Liu, Y, Jin, L, Xu, Z, Liu, P, Zhao, G, Wang, J, Svirskas, ŠN, Banys, JR, Park, CH, Frankcombe, TJ, Wei, X & Liu, Y 2021, 'Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO₂', ACS applied materials & interfaces, vol. 13, no. 45, pp. 54124-54132. https://doi.org/10.1021/acsami.1c09632

TY - JOUR

T1 - Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO2

AU - Jiang, Mengqi

AU - Hu, Wanbiao

AU - Jacob, Lilit

AU - Sun, Qingbo

AU - Cox, Nicholas

AU - Kim, Doukyun

AU - Tian, Ye

AU - Zhao, Luyang

AU - Liu, Yang

AU - Jin, Li

AU - Xu, Zhuo

AU - Liu, Peng

AU - Zhao, Gang

AU - Wang, Jian

AU - Svirskas, Šarū Nas

AU - Banys, Jū Ras

AU - Park, Chul Hong

AU - Frankcombe, Terry J.

AU - Wei, Xiaoyong

AU - Liu, Yun

PY - 2021/11/17

Y1 - 2021/11/17

N2 - High permittivity materials for a gigahertz (GHz) communication technology have been actively sought for some time. Unfortunately, in most materials, the dielectric constant starts to drop as frequencies increase through the megahertz (MHz) range. In this work, we report a large dielectric constant of ∼800 observed in defect-mediated rutile SnO2 ceramics, which is nearly frequency and temperature independent over the frequency range of 1 mHz to 35 GHz and temperature range of 50-450 K. Experimental and theoretical investigations demonstrate that the origin of the high dielectric constant can be attributed to the formation of locally well-defined Zn2+-Nb4+ defect clusters, which create hole-pinned defect dipoles. We believe that this work provides a promising strategy to advance dipole polarization theory and opens up a direction for the design and development of high frequency, broadband dielectric materials for use in future communication technology.

AB - High permittivity materials for a gigahertz (GHz) communication technology have been actively sought for some time. Unfortunately, in most materials, the dielectric constant starts to drop as frequencies increase through the megahertz (MHz) range. In this work, we report a large dielectric constant of ∼800 observed in defect-mediated rutile SnO2 ceramics, which is nearly frequency and temperature independent over the frequency range of 1 mHz to 35 GHz and temperature range of 50-450 K. Experimental and theoretical investigations demonstrate that the origin of the high dielectric constant can be attributed to the formation of locally well-defined Zn2+-Nb4+ defect clusters, which create hole-pinned defect dipoles. We believe that this work provides a promising strategy to advance dipole polarization theory and opens up a direction for the design and development of high frequency, broadband dielectric materials for use in future communication technology.

KW - SnO

KW - codoping

KW - defect clusters

KW - gigahertz

KW - high-frequency dielectric property

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U2 - 10.1021/acsami.1c09632

DO - 10.1021/acsami.1c09632

M3 - Article

SN - 1944-8244

VL - 13

SP - 54124

EP - 54132

JO - ACS applied materials & interfaces

JF - ACS applied materials & interfaces

IS - 45

ER -

Hole-pinned defect clusters for a large dielectric constant up to GHz in Zinc and niobium codoped rutile SnO₂

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