Understanding contact electrification at liquid–solid interfaces from surface electronic structure

AbstractThe charge transfer phenomenon of contact electrification even exists in the liquid–solid interface by a tiny droplet on the solid surface. In this work, we have investigated the contact electrification mechanism at the liquid–solid interface from the electronic structures at the atomic level. The electronic structures display stronger modulations by the outmost shell charge transfer via surface electrostatic charge perturbation than the inter-bonding-orbital charge transfer at the liquid–solid interface, supporting more factors being involved in charge transfer via contact electrification. Meanwhile, we introduce the electrochemical cell model to quantify the charge transfer based on the pinning factor to linearly correlate the charge transfer and the electronic structures. The pinning factor exhibits a more direct visualization of the charge transfer at the liquid–solid interface. This work supplies critical guidance for describing, quantifying, and modulating the contact electrification induced charge transfer systems in triboelectric nanogenerators in future works.

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Networks of High Performance Triboelectric Nanogenerators Based on Liquid-Solid Interface Contact Electrification for Harvesting Low-Frequency Blue Energy

Advanced Energy Materials ◽

10.1002/aenm.201800705 ◽

2018 ◽

Vol 8 (21) ◽

pp. 1800705 ◽

Cited By ~ 54

Author(s):

Xiaoyi Li ◽

Juan Tao ◽

Xiandi Wang ◽

Jing Zhu ◽

Caofeng Pan ◽

...

Keyword(s):

High Performance ◽

Low Frequency ◽

Solid Interface ◽

Contact Electrification ◽

Interface Contact ◽

Triboelectric Nanogenerators

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Measurement and Analysis of Triboelectric Surface Charge

Physics and High Technology ◽

10.3938/phit.30.002 ◽

2021 ◽

Vol 30 (1/2) ◽

pp. 7-11

Author(s):

Jinhong PARK ◽

Jinhyeok CHOI ◽

Sang Hyeok PARK ◽

Minbaek LEE

Keyword(s):

Electron Transfer ◽

Charge Transfer ◽

Surface Properties ◽

Elastic Moduli ◽

Surface Charges ◽

Contact Electrification ◽

Measurement And Analysis ◽

Different Types ◽

Triboelectric Charging ◽

Method Of Measurement

Contact electrification occurs when two isolated objects come into contact. Such a phenomenon led humans to first realization of the existence of electricity. Until now, the main causes of the triboelectric charging phenomenon have generally been thought to be the transfer of electrons, ions, and materials. This article, however, is limited to electron transfer on the surface, which is regarded as a general case not limited to specific situations. The contact between two objects occurs between the two surfaces; therefore, the surface properties of the material under examination are the most important properties in triboelectric charge transfer. The surface properties may include the types of materials in contact, their energy states, the roughnesses of their surfaces, and their elastic moduli. In this regard, we introduce here the current understanding of the energy band structures involved in the different types of materials, the method of measurement, an analysis of surface charges, and related applications.

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Mechanism of Contact Electrification

Physics and High Technology ◽

10.3938/phit.30.001 ◽

2021 ◽

Vol 30 (1/2) ◽

pp. 2-6

Author(s):

Young-Joon KO ◽

Dong Woo LEE ◽

Jonghoon JUNG

Keyword(s):

Charge Transfer ◽

Thermionic Emission ◽

Force Model ◽

Emission Model ◽

Intermolecular Force ◽

Important Research ◽

Charge Transfer Mechanism ◽

Contact Electrification ◽

Schottky Model ◽

Thermionic Emission Model

Contact electrification has been a well-known phenomenon since B.C. 300. However, the origin of triboelectric charge and the charge transfer mechanism are not well understood. To date, the thermionic emission model, Schottky model, flexoelectric model, and intermolecular force model have been proposed for the contact electrification in conductors, semiconductors, and insulators. This article briefly introduces several important research results on the simple-seeming, but baffling, topic of contact electrification.

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En route to a unified model for photo-electrochemical reactor optimisation. I - Photocurrent and H2 yield predictions

Journal of Materials Chemistry A ◽

10.1039/c7ta05125e ◽

2017 ◽

Vol 5 (43) ◽

pp. 22683-22696 ◽

Cited By ~ 8

Author(s):

Franky E. Bedoya-Lora ◽

Anna Hankin ◽

Geoff H. Kelsall

Keyword(s):

Electrochemical Cell ◽

Cell Model ◽

Bubble Formation ◽

Electrochemical Reactor ◽

Photon Flux ◽

Recombination Rates ◽

Electron Hole ◽

Gas Desorption ◽

H2 Yield ◽

Hole Recombination

A photo-electrochemical cell model was developed accounting for photon flux, electron–hole recombination rates, gas desorption, bubble formation and cross-over losses.

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Application of the High Temperature Fermi Probe in Studies of Charge Transfer at the Gas/Solid Interface. Example of the Oxygen/Zirconia System

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.253.151 ◽

2003 ◽

Vol 253 ◽

pp. 151-178 ◽

Cited By ~ 3

Author(s):

Tadeusz Bak ◽

Janusz Nowotny ◽

M. Rekas ◽

Charles C. Sorrell

Keyword(s):

Charge Transfer ◽

High Temperature ◽

Solid Interface

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Basic study of model based development of lithium-ion battery using Co-simulation of vehicle system model and electrochemical cell model

The Proceedings of Mechanical Engineering Congress Japan ◽

10.1299/jsmemecj.2020.j12102 ◽

2020 ◽

Vol 2020 (0) ◽

pp. J12102

Author(s):

Ena ISHII ◽

Ryosuke YAGI ◽

Takamitsu SUNAOSHI ◽

Norihiro YOSHINAGA

Keyword(s):

Lithium Ion Battery ◽

Electrochemical Cell ◽

Cell Model ◽

Lithium Ion ◽

System Model ◽

Basic Study ◽

Model Based ◽

Vehicle System

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THE ELECTRONIC STRUCTURE AT ORGANIC–2D MATERIAL HETEROINTERFACES

Surface Review and Letters ◽

10.1142/s0218625x21400035 ◽

2021 ◽

pp. 2140003

Author(s):

YU LI HUANG ◽

ANDREW THYE SHEN WEE

Keyword(s):

Charge Transfer ◽

Electronic Structures ◽

Transition Metal Dichalcogenides ◽

2D Material ◽

Physical Mechanisms ◽

Wide Range ◽

Fundamental Understanding ◽

Potential Applications ◽

Metal Dichalcogenides ◽

Interfacial Charge

Organic–2D material heterostructures have attracted intensive research interest due to their intriguing properties, with a wide range of potential applications in multifunctional flexible electronic and optoelectronic devices. Central to the realization of such devices is a fundamental understanding of the electronic structures at organic–2D material heterointerfaces. The energy level alignment (ELA) at the interface is of paramount importance because it determines the charge transfer barriers between the two materials in contact. In this paper, we discuss the physical mechanisms determining the ELAs, with special attention on interfacial charge transfer at the heterostructures. We review the current understanding of electronic properties at the heterointerfaces formed by the integration of organics with graphene and 2D transition metal dichalcogenides (TMDs), and conclude with a perspective on the future development of organic–2D material heterostructure.

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