Improving Relative Permittivity and Suppressing Dielectric Loss of Triboelectric Layers for High-Performance Wearable Electricity Generation

Zehua Peng; Xiao Xiao; Jianxin Song; Alberto Libanori; Ching Lee; Keda Chen; Yuan Gao; Yunsheng Fang; Juan Wang; Zuankai Wang; Jun Chen; Michael K. H. Leung

doi:10.1021/acsnano.2c05820

Improving Relative Permittivity and Suppressing Dielectric Loss of Triboelectric Layers for High-Performance Wearable Electricity Generation

Zehua Peng, Xiao Xiao, Jianxin Song, Alberto Libanori, Ching Lee, Keda Chen, Yuan Gao, Yunsheng Fang, Juan Wang, Zuankai Wang, Jun Chen^*, Michael K. H. Leung^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

47 Citations (Scopus)

Abstract

High relative permittivity and low dielectric loss are two desired parameters of a triboelectric layer to enhance its mechanical-to-electrical energy conversion efficiency in a triboelectric nanogenerator (TENG). However, the elevated permittivity of the triboelectric layer is always accompanied by increasing dielectric loss, limiting further improvement or even reducing the electrical output. Herein, we report a method for improving the relative permittivity and suppressing the dielectric loss of the triboelectric layer via nanoscale design at the particle-polymer interface. When incorporated with 2 wt % Ag@C, the triboelectric-layer-enhanced TENG (TLE-TENG) presents a 2.6-fold increment in relative permittivity and a 302% current enhancement. An instantaneous peak power density of 1.22 W m^-2, an excellent pressure sensitivity of 90.95 V kPa^-1, and an optimized sheet resistance (∼0.14 Ω/sq) are attributes of this greatly enhanced device. Such improvements bode well for the implementation of these enhancing strategies to help position TLE-TENGs as pervasive and sustainable power sources and active self-powered sensors in the era of the Internet of Things.

Original language	English
Pages (from-to)	20251–20262
Journal	ACS Nano
Volume	16
Issue number	12
Online published	15 Dec 2022
DOIs	https://doi.org/10.1021/acsnano.2c05820
Publication status	Published - 27 Dec 2022

Funding

M.K.H.L. acknowledges the National Natural Science Foundation of China (No. 21875200) and the Hong Kong Research Grants Council/General Research Fund (No. 11206520). J.C. acknowledges the Henry Samueli School of Engineering & Applied Science and the Department of Bioengineering at the University of California for startup support. The authors thank Dr. Lingyun Wang, Mr. Jihong Shi, and Mr. Kelong Ao, School of Energy and Environment, City University of Hong Kong, for assistance in technical support of the equipment.

Research Keywords

triboelectric nanogenerator
carbon-coated silver nanofillers
relative permittivity
dielectric loss
flexibility
self-powered sensing
SURFACE FUNCTIONALIZATION
ENERGY
NANOGENERATORS
IMPEDANCE
POWER

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title = "Improving Relative Permittivity and Suppressing Dielectric Loss of Triboelectric Layers for High-Performance Wearable Electricity Generation",

abstract = "High relative permittivity and low dielectric loss are two desired parameters of a triboelectric layer to enhance its mechanical-to-electrical energy conversion efficiency in a triboelectric nanogenerator (TENG). However, the elevated permittivity of the triboelectric layer is always accompanied by increasing dielectric loss, limiting further improvement or even reducing the electrical output. Herein, we report a method for improving the relative permittivity and suppressing the dielectric loss of the triboelectric layer via nanoscale design at the particle-polymer interface. When incorporated with 2 wt % Ag@C, the triboelectric-layer-enhanced TENG (TLE-TENG) presents a 2.6-fold increment in relative permittivity and a 302% current enhancement. An instantaneous peak power density of 1.22 W m-2, an excellent pressure sensitivity of 90.95 V kPa-1, and an optimized sheet resistance (∼0.14 Ω/sq) are attributes of this greatly enhanced device. Such improvements bode well for the implementation of these enhancing strategies to help position TLE-TENGs as pervasive and sustainable power sources and active self-powered sensors in the era of the Internet of Things.",

keywords = "triboelectric nanogenerator, carbon-coated silver nanofillers, relative permittivity, dielectric loss, flexibility, self-powered sensing, SURFACE FUNCTIONALIZATION, ENERGY, NANOGENERATORS, IMPEDANCE, POWER",

author = "Zehua Peng and Xiao Xiao and Jianxin Song and Alberto Libanori and Ching Lee and Keda Chen and Yuan Gao and Yunsheng Fang and Juan Wang and Zuankai Wang and Jun Chen and Leung, {Michael K. H.}",

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T1 - Improving Relative Permittivity and Suppressing Dielectric Loss of Triboelectric Layers for High-Performance Wearable Electricity Generation

AU - Peng, Zehua

AU - Xiao, Xiao

AU - Song, Jianxin

AU - Libanori, Alberto

AU - Lee, Ching

AU - Chen, Keda

AU - Gao, Yuan

AU - Fang, Yunsheng

AU - Wang, Juan

AU - Wang, Zuankai

AU - Chen, Jun

AU - Leung, Michael K. H.

PY - 2022/12/27

Y1 - 2022/12/27

N2 - High relative permittivity and low dielectric loss are two desired parameters of a triboelectric layer to enhance its mechanical-to-electrical energy conversion efficiency in a triboelectric nanogenerator (TENG). However, the elevated permittivity of the triboelectric layer is always accompanied by increasing dielectric loss, limiting further improvement or even reducing the electrical output. Herein, we report a method for improving the relative permittivity and suppressing the dielectric loss of the triboelectric layer via nanoscale design at the particle-polymer interface. When incorporated with 2 wt % Ag@C, the triboelectric-layer-enhanced TENG (TLE-TENG) presents a 2.6-fold increment in relative permittivity and a 302% current enhancement. An instantaneous peak power density of 1.22 W m-2, an excellent pressure sensitivity of 90.95 V kPa-1, and an optimized sheet resistance (∼0.14 Ω/sq) are attributes of this greatly enhanced device. Such improvements bode well for the implementation of these enhancing strategies to help position TLE-TENGs as pervasive and sustainable power sources and active self-powered sensors in the era of the Internet of Things.

AB - High relative permittivity and low dielectric loss are two desired parameters of a triboelectric layer to enhance its mechanical-to-electrical energy conversion efficiency in a triboelectric nanogenerator (TENG). However, the elevated permittivity of the triboelectric layer is always accompanied by increasing dielectric loss, limiting further improvement or even reducing the electrical output. Herein, we report a method for improving the relative permittivity and suppressing the dielectric loss of the triboelectric layer via nanoscale design at the particle-polymer interface. When incorporated with 2 wt % Ag@C, the triboelectric-layer-enhanced TENG (TLE-TENG) presents a 2.6-fold increment in relative permittivity and a 302% current enhancement. An instantaneous peak power density of 1.22 W m-2, an excellent pressure sensitivity of 90.95 V kPa-1, and an optimized sheet resistance (∼0.14 Ω/sq) are attributes of this greatly enhanced device. Such improvements bode well for the implementation of these enhancing strategies to help position TLE-TENGs as pervasive and sustainable power sources and active self-powered sensors in the era of the Internet of Things.

KW - triboelectric nanogenerator

KW - carbon-coated silver nanofillers

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KW - dielectric loss

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KW - self-powered sensing

KW - SURFACE FUNCTIONALIZATION

KW - ENERGY

KW - NANOGENERATORS

KW - IMPEDANCE

KW - POWER

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JO - ACS Nano

JF - ACS Nano

IS - 12

ER -

Improving Relative Permittivity and Suppressing Dielectric Loss of Triboelectric Layers for High-Performance Wearable Electricity Generation

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GRF: Rational Design of MoS2 Electrocatalyst for pH-universal Hydrogen Evolution: Mechanisms, Kinetics and Optimization

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Improving Relative Permittivity and Suppressing Dielectric Loss of Triboelectric Layers for High-Performance Wearable Electricity Generation

Abstract

Funding

Research Keywords

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GRF: Rational Design of MoS2 Electrocatalyst for pH-universal Hydrogen Evolution: Mechanisms, Kinetics and Optimization

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