分子桥连石墨烯/银用于高性能导电浆料

Translated title of the contribution: Molecule bridged graphene/Ag for highly conductive ink

Weixin Li, Jianmin Yan, Cong Wang, Ning Zhang, Tsz Hin Choy, Su Liu, Lei Zhao, Xiaoming Tao, Yang Chai

Research output: Journal article publicationJournal articleAcademic researchpeer-review

6 Citations (Scopus)

Abstract

Printing is a method of additive manufacturing that can reduce material costs and environmental contamination during the fabrication process. Ag ink is commonly used in printed electronics, such as interconnects, inductors, and antennas. However, the high cost of noble Ag restricts its massive applications. To reduce the cost of the state-of-the-art Ag ink and realize large-scale manufacturing, we develop a molecule-bridged graphene/Ag (MB-G/A) composite to produce highly conductive and cost-effective paper-based electronics. Graphene can be used to substitute part of Ag nanoparticles to reduce costs, form a conducive percolation network, and retain a reasonable level of conductivity. We adopt cysteamine as a molecular linker, because it anchors on the surface of graphene via the diazonium reaction. Additionally, the thiol functional group on the other end of cysteamine can bond to a Ag atom, forming a molecular bridge between graphene and Ag and promoting electron transport between Ag and graphene. As a result, the maximum conductivity of MB-G/A inks can reach 2.0 × 10 5 S m −1, enabling their successful application in various printable electronics. In addition, the optimum MB-G/A ink costs less than half as much as pure Ag inks, showing the great potential of MB-G/A ink in commercial electronic devices. [Figure not available: see fulltext.]

Translated title of the contributionMolecule bridged graphene/Ag for highly conductive ink
Original languageChinese (Simplified)
Pages (from-to)2771-2778
Number of pages8
JournalScience China Materials
Volume65
Issue number10
DOIs
Publication statusPublished - Jun 2022

Keywords

  • Ag
  • conductivity
  • flexible electronics
  • graphene
  • molecule modification

ASJC Scopus subject areas

  • General Materials Science

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