Microwave Dielectric Materials with Defect-Dipole Clusters Induced Colossal Permittivity and Ultra-low Loss

Jianmei Liu; Lilit Jacob; Julien Langley; Zhenxiao Fu; Xiuhua Cao; Shiwo Ta; Hua Chen; Ŝarū Nas Svirskas; Jū Ras Banys; Xiaoyong Wei; Nicholas Cox; Terry J. Frankcombe; Yun Liu

doi:10.1021/acsaelm.1c00236

Microwave Dielectric Materials with Defect-Dipole Clusters Induced Colossal Permittivity and Ultra-low Loss

Jianmei Liu, Lilit Jacob, Julien Langley, Zhenxiao Fu, Xiuhua Cao, Shiwo Ta, Hua Chen, Ŝarū Nas Svirskas, Jū Ras Banys, Xiaoyong Wei, Nicholas Cox^*, Terry J. Frankcombe^*, Yun Liu^*

^*Corresponding author for this work

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

10 Citations (Scopus)

Abstract

Microwave dielectric materials are of great interest due to their applications in communication technology. The intrinsically low dielectric permittivity (generally less than 100) of traditional microwave dielectric materials has limited their capability in reducing the device size and developing various applications. In this paper, we report a microwave dielectric material, (La + Nb) co-doped BaSnO3, which exhibits both frequency- and temperature-independent colossal permittivity (ϵ > 103) over the frequency range from 10 Hz to microwave region (∼1 GHz) while retaining the ultra-low dielectric loss of 4 × 10-4, equivalent to a quality factor Qf (GHz) ∼2500. Systemic defect analysis and density functional theory calculations suggest that negatively charged La and positively charged Nb octahedra are correlated adjacent to each other along the [110] direction, forming defect-dipole clusters, which lead to their microwave dielectric properties. This work presents insights on the development of microwave dielectric materials that offer many potentials for microwave dielectric devices and their associated applications in future communication technology.

Original language	English
Pages (from-to)	5015-5022
Number of pages	8
Journal	ACS Applied Electronic Materials
Volume	3
Issue number	11
DOIs	https://doi.org/10.1021/acsaelm.1c00236
Publication status	Published - 23 Nov 2021

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title = "Microwave Dielectric Materials with Defect-Dipole Clusters Induced Colossal Permittivity and Ultra-low Loss",

abstract = "Microwave dielectric materials are of great interest due to their applications in communication technology. The intrinsically low dielectric permittivity (generally less than 100) of traditional microwave dielectric materials has limited their capability in reducing the device size and developing various applications. In this paper, we report a microwave dielectric material, (La + Nb) co-doped BaSnO3, which exhibits both frequency- and temperature-independent colossal permittivity (ϵ > 103) over the frequency range from 10 Hz to microwave region (∼1 GHz) while retaining the ultra-low dielectric loss of 4 × 10-4, equivalent to a quality factor Qf (GHz) ∼2500. Systemic defect analysis and density functional theory calculations suggest that negatively charged La and positively charged Nb octahedra are correlated adjacent to each other along the [110] direction, forming defect-dipole clusters, which lead to their microwave dielectric properties. This work presents insights on the development of microwave dielectric materials that offer many potentials for microwave dielectric devices and their associated applications in future communication technology.",

keywords = "co-doped BaSnO, colossal permittivity, defect clusters, defect dipole polarization, microwave dielectric materials",

author = "Jianmei Liu and Lilit Jacob and Julien Langley and Zhenxiao Fu and Xiuhua Cao and Shiwo Ta and Hua Chen and Svirskas, {Ŝarū Nas} and Banys, {Jū Ras} and Xiaoyong Wei and Nicholas Cox and Frankcombe, {Terry J.} and Yun Liu",

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

year = "2021",

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doi = "10.1021/acsaelm.1c00236",

language = "English",

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T1 - Microwave Dielectric Materials with Defect-Dipole Clusters Induced Colossal Permittivity and Ultra-low Loss

AU - Liu, Jianmei

AU - Jacob, Lilit

AU - Langley, Julien

AU - Fu, Zhenxiao

AU - Cao, Xiuhua

AU - Ta, Shiwo

AU - Chen, Hua

AU - Svirskas, Ŝarū Nas

AU - Banys, Jū Ras

AU - Wei, Xiaoyong

AU - Cox, Nicholas

AU - Frankcombe, Terry J.

AU - Liu, Yun

PY - 2021/11/23

Y1 - 2021/11/23

N2 - Microwave dielectric materials are of great interest due to their applications in communication technology. The intrinsically low dielectric permittivity (generally less than 100) of traditional microwave dielectric materials has limited their capability in reducing the device size and developing various applications. In this paper, we report a microwave dielectric material, (La + Nb) co-doped BaSnO3, which exhibits both frequency- and temperature-independent colossal permittivity (ϵ > 103) over the frequency range from 10 Hz to microwave region (∼1 GHz) while retaining the ultra-low dielectric loss of 4 × 10-4, equivalent to a quality factor Qf (GHz) ∼2500. Systemic defect analysis and density functional theory calculations suggest that negatively charged La and positively charged Nb octahedra are correlated adjacent to each other along the [110] direction, forming defect-dipole clusters, which lead to their microwave dielectric properties. This work presents insights on the development of microwave dielectric materials that offer many potentials for microwave dielectric devices and their associated applications in future communication technology.

AB - Microwave dielectric materials are of great interest due to their applications in communication technology. The intrinsically low dielectric permittivity (generally less than 100) of traditional microwave dielectric materials has limited their capability in reducing the device size and developing various applications. In this paper, we report a microwave dielectric material, (La + Nb) co-doped BaSnO3, which exhibits both frequency- and temperature-independent colossal permittivity (ϵ > 103) over the frequency range from 10 Hz to microwave region (∼1 GHz) while retaining the ultra-low dielectric loss of 4 × 10-4, equivalent to a quality factor Qf (GHz) ∼2500. Systemic defect analysis and density functional theory calculations suggest that negatively charged La and positively charged Nb octahedra are correlated adjacent to each other along the [110] direction, forming defect-dipole clusters, which lead to their microwave dielectric properties. This work presents insights on the development of microwave dielectric materials that offer many potentials for microwave dielectric devices and their associated applications in future communication technology.

KW - co-doped BaSnO

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KW - defect clusters

KW - defect dipole polarization

KW - microwave dielectric materials

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DO - 10.1021/acsaelm.1c00236

M3 - Article

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JO - ACS Applied Electronic Materials

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ER -

Microwave Dielectric Materials with Defect-Dipole Clusters Induced Colossal Permittivity and Ultra-low Loss

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