An effective formaldehyde gas sensor based on oxygen-rich three-dimensional graphene

Shu Zhang; Jinbo Pang; Yufen Li; Bergoi Ibarlucea; Yu Liu; Ting Wang; Xiaoyan Liu; Songang Peng; Thomas Gemming; Qilin Cheng; Hong Liu; Jiali Yang; Gianaurelio Cuniberti; Weijia Zhou; Mark H. Rümmeli

doi:10.1088/1361-6528/ac4eb4

An effective formaldehyde gas sensor based on oxygen-rich three-dimensional graphene

Shu Zhang
, Jinbo Pang^*
, Yufen Li
, Bergoi Ibarlucea
, Yu Liu
, Ting Wang
, Xiaoyan Liu
, Songang Peng
, Thomas Gemming
, Qilin Cheng
, Hong Liu^*
, Jiali Yang
, Gianaurelio Cuniberti^*
, Weijia Zhou
, Mark H. Rümmeli^*

^*Autor correspondiente de este trabajo

Shandong University
University of Jinan
Technische Universität Dresden
Soochow University
Qilu University of Technology
CAS - Institute of Microelectronics
Leibniz Institute for Solid State and Materials Research Dresden
Polish Academy of Sciences
VŠB – Technical University of Ostrava

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

24 Citas (Scopus)

Resumen

Three-dimensional (3D) graphene with a high specific surface area and excellent electrical conductivity holds extraordinary potential for molecular gas sensing. Gas molecules adsorbed onto graphene serve as electron donors, leading to an increase in conductivity. However, several challenges remain for 3D graphene-based gas sensors, such as slow response and long recovery time. Therefore, research interest remains in the promotion of the sensitivity of molecular gas detection. In this study, we fabricate oxygen plasma-treated 3D graphene for the high-performance gas sensing of formaldehyde. We synthesize large-area, high-quality, 3D graphene over Ni foam by chemical vapor deposition and obtain freestanding 3D graphene foam after Ni etching. We compare three types of strategies - non-treatment, oxygen plasma, and etching in HNO3 solution - for the posttreatment of 3D graphene. Eventually, the strategy for oxygen plasma-treated 3D graphene exceeds expectations, which may highlight the general gas sensing based on chemiresistors.

Idioma original	Inglés
Número de artículo	185702
Publicación	Nanotechnology
Volumen	33
N.º	18
DOI	https://doi.org/10.1088/1361-6528/ac4eb4
Estado	Publicada - 30 abr 2022
Publicado de forma externa	Sí

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title = "An effective formaldehyde gas sensor based on oxygen-rich three-dimensional graphene",

abstract = "Three-dimensional (3D) graphene with a high specific surface area and excellent electrical conductivity holds extraordinary potential for molecular gas sensing. Gas molecules adsorbed onto graphene serve as electron donors, leading to an increase in conductivity. However, several challenges remain for 3D graphene-based gas sensors, such as slow response and long recovery time. Therefore, research interest remains in the promotion of the sensitivity of molecular gas detection. In this study, we fabricate oxygen plasma-treated 3D graphene for the high-performance gas sensing of formaldehyde. We synthesize large-area, high-quality, 3D graphene over Ni foam by chemical vapor deposition and obtain freestanding 3D graphene foam after Ni etching. We compare three types of strategies - non-treatment, oxygen plasma, and etching in HNO3 solution - for the posttreatment of 3D graphene. Eventually, the strategy for oxygen plasma-treated 3D graphene exceeds expectations, which may highlight the general gas sensing based on chemiresistors.",

keywords = "3D graphene, chemical vapor deposition, chemiresistors, gas sensing, oxygen plasma treatments",

author = "Shu Zhang and Jinbo Pang and Yufen Li and Bergoi Ibarlucea and Yu Liu and Ting Wang and Xiaoyan Liu and Songang Peng and Thomas Gemming and Qilin Cheng and Hong Liu and Jiali Yang and Gianaurelio Cuniberti and Weijia Zhou and R{\"u}mmeli, \{Mark H.\}",

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AU - Zhang, Shu

AU - Pang, Jinbo

AU - Li, Yufen

AU - Ibarlucea, Bergoi

AU - Liu, Yu

AU - Wang, Ting

AU - Liu, Xiaoyan

AU - Peng, Songang

AU - Gemming, Thomas

AU - Cheng, Qilin

AU - Liu, Hong

AU - Yang, Jiali

AU - Cuniberti, Gianaurelio

AU - Zhou, Weijia

AU - Rümmeli, Mark H.

PY - 2022/4/30

Y1 - 2022/4/30

N2 - Three-dimensional (3D) graphene with a high specific surface area and excellent electrical conductivity holds extraordinary potential for molecular gas sensing. Gas molecules adsorbed onto graphene serve as electron donors, leading to an increase in conductivity. However, several challenges remain for 3D graphene-based gas sensors, such as slow response and long recovery time. Therefore, research interest remains in the promotion of the sensitivity of molecular gas detection. In this study, we fabricate oxygen plasma-treated 3D graphene for the high-performance gas sensing of formaldehyde. We synthesize large-area, high-quality, 3D graphene over Ni foam by chemical vapor deposition and obtain freestanding 3D graphene foam after Ni etching. We compare three types of strategies - non-treatment, oxygen plasma, and etching in HNO3 solution - for the posttreatment of 3D graphene. Eventually, the strategy for oxygen plasma-treated 3D graphene exceeds expectations, which may highlight the general gas sensing based on chemiresistors.

AB - Three-dimensional (3D) graphene with a high specific surface area and excellent electrical conductivity holds extraordinary potential for molecular gas sensing. Gas molecules adsorbed onto graphene serve as electron donors, leading to an increase in conductivity. However, several challenges remain for 3D graphene-based gas sensors, such as slow response and long recovery time. Therefore, research interest remains in the promotion of the sensitivity of molecular gas detection. In this study, we fabricate oxygen plasma-treated 3D graphene for the high-performance gas sensing of formaldehyde. We synthesize large-area, high-quality, 3D graphene over Ni foam by chemical vapor deposition and obtain freestanding 3D graphene foam after Ni etching. We compare three types of strategies - non-treatment, oxygen plasma, and etching in HNO3 solution - for the posttreatment of 3D graphene. Eventually, the strategy for oxygen plasma-treated 3D graphene exceeds expectations, which may highlight the general gas sensing based on chemiresistors.

KW - 3D graphene

KW - chemical vapor deposition

KW - chemiresistors

KW - gas sensing

KW - oxygen plasma treatments

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JO - Nanotechnology

JF - Nanotechnology

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ER -

An effective formaldehyde gas sensor based on oxygen-rich three-dimensional graphene

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