Variations in the Effective Work Function of Graphene in a Sliding Electrical Contact Interface under Ambient Conditions

Huang, Shuei-De; Chu, En-De; Wang, Yuhan; Liou, Jhe-Wei; Wang, Ruei-Si; Woon, Wei Yen; Chiu, Hsiang Chih

doi:10.1021/acsami.2c02096

Cited by 2 publications

(1 citation statement)

References 66 publications

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“…Up to now, the research methods of CE have covered theory, experiment and simulation [17]. In order to analyze the process and mechanism of electron transfer in CE more accurately, theories such as extending the most basic Maxwell equations [18] to contact surface charge mosaic effect [19], electron cloud potential well model based on electron emission [20], mass transfer and electron transfer under electric field [21], the theoretical boundary under the air breakdown restriction [22], and effective work function change [23] have been put forward continuously. These models strongly promoted CE experiments.…”

Section: Introductionmentioning

confidence: 99%

On the contact electrification mechanism in semiconductor–semiconductor case by vertical contact-separation triboelectric nanogenerator

He¹,

Tian²,

Peng³

et al. 2023

Nanotechnology

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With the speed of industrialization accelerating, the traditional energy is in the predicament of being exhausted. Humans urgently need a clean energy to maintain the peace and development. Triboelectric nanogenerator (TENG) is a tiny device that collects and converts the renewable energy, such as wind, vibration and tidal/blue energy, into electrical energy. As the most significant working principle of TENG, contact electrification (CE) has been broadly studied since it was documented thousands of years ago. A large number of related researches are reported. However, most of them are focused on the polymer materials, device structures and potential applications. There are few literatures about the mechanism of CE, especially in the semiconductor-semiconductor case. Semiconductor-semiconductor CE is a promising method to generate electricity, which has been used in many fields, such as the photodetector and displacement sensor. Therefore, it is necessary to establish a serious and detailed theory in order to deeply explain the underlying mechanisms of semiconductor-semiconductor CE. In this work, a novel Fermi level model based on energy band theory is proposed to illustrate the semiconductor-semiconductor CE mechanism. By assembling a ZnO/Si vertical contact-separation (CS) mode TENG, the charge transfer introduced by CE is systematically measured. According to the energy band theory and TENG governing equation, the experimental data is qualitatively and quantitatively analyzed. Moreover, the effects of different concentrations of growth solutions on the morphology of ZnO nanowires and the Fermi level difference between ZnO and Si are explored as well. Results show that it is the Fermi level difference that dominates the short circuit transfer charge amount and direction of semiconductor-semiconductor CE mechanism. Our work can be applied to understand the CE mechanism in semiconductor-semiconductor case and broaden the application prospects of semiconductor-based TENG.

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