石墨烯基电场传感器研发与测试

doi:10.11720/wtyht.2024.0152

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Abstract

This study aims to enhance the measurement accuracy of the electric field by reducing the range shifting and background noise of electric field sensors in the electromagnetic detection system. First, it ascertained the design requirements of electric field sensors by investigating the mechanisms of the range drift and background noise. Second, it established the Ag-AgCl-based preparation process for graphene-based stable electrolyte gel. Third, it optimized the multi-cell multi-contactor electrode structure based on polymeric microporous membranes. Finally, it developed a graphene-based electric field sensor characterized by low range drift and background noise. This sensor can retard internal ion diffusion by leveraging the ion retention ability of graphene and the multi-cell structure composed of reaction, transition, and buffer zones. Consequently, the range drift caused by changes in the ion concentration is reduced. The internal and contact resistance of this sensor can be reduced through the conductive ability of graphene and the enhanced contact with the ground via multiple contactors, respectively, thereby reducing the sensor's background noise. The graphene-based electric field sensor developed in this study shows range drift not exceeding 20 μV/24 h, and background noise not above 25 nV/√Hz. This sensor was applied to a 24 h field magnetotelluric sounding test conducted in the Duobaoshan area, Heilongjiang Province, yielding high-quality electric field data in the frequency band of 0.000 125~320 Hz, with the apparent resistivity phase curve aligning with the result of commercial electrodes. Therefore, the graphene-based electric field sensor proves effective in fieldwork.

Key words： electromagnetic detection electric field sensor graphene low range drift low noise

Received: 07 April 2024 Published: 08 January 2025

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	Articles by authors
	Li-Li KANG
	Yong-You YANG
	Zhong-Xing WANG
	Kai CHEN
	Peng HE
	Xu-Zhe WANG
	Gu-Qiao DING
	Zi-Hang LI

Cite this article:

Li-Li KANG,Yong-You YANG,Zhong-Xing WANG, et al. R&D and tests of a graphene-based electric field sensor[J]. Geophysical and Geochemical Exploration, 2024, 48(6): 1463-1470.

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https://www.wutanyuhuatan.com/EN/10.11720/wtyht.2024.0152 OR https://www.wutanyuhuatan.com/EN/Y2024/V48/I6/1463

Equivalent model of electric field measurement circuit

Schematic diagram of electrochemical reaction process of non-polarized electrode with Ag-AgCl system

Morphology of graphene oxide gel with different mass ratio

Comparison of water retention properties of graphene oxide gels with different mass ratio

Design diagram of multi-contactor electric field sensor structure

Overlooking partition diagram of multi-contactor electric field sensor structure

Measurement platform of potential difference and drift

Comparison results for 5 days of the potential difference and drift

Comparison results the potential drift for one day

Results of the potential drift per day for 5 consecutive days

设备名	用途	主要技术指标	实物图片
高精度多路噪声分析装置	噪声测量	本底噪声优于10nV/ $H z$ @1Hz; 观测带宽 DC~1000Hz

Noise test equipment and its parameter index

Comparison results of noise test

Layout of magnetotelluric field test device

Field comparison results of electric field, apparent resistivity and phase

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