Room Temperature‐Sintering Conductive Ink Fabricated from Oleic‐Modified Graphene for the Flexible Electronic Devices

Room Temperature‐Sintering Conductive Ink Fabricated from Oleic‐Modified Graphene for the Flexible Electronic Devices

Graphene, a novel 2D nanomaterial, has been intensively studied and utilized in many fields of applications. Graphene‐based conductive ink has attracted many scientific researchers due to its flexibility, durability, and, most importantly, high electrical conductivity. However, the low dispensabilit...

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Bibliographic Details
Published in:ChemistrySelect (Weinheim) Vol. 7; no. 4
Main Authors: Le, Tam The, Bui, Huy Hoang Tran, Dinh, An Khang Phung, Van, Duc Vu, Ho, Quang Dinh, Thi, Hoai An Nguyen, Nguyen, Du Hoa, La, Duong Duc
Format: Journal Article
Language:English
Published: 27-01-2022
Subjects:
conductive ink
flexible electronic devices
Graphene
nanotechnology
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Summary:Graphene, a novel 2D nanomaterial, has been intensively studied and utilized in many fields of applications. Graphene‐based conductive ink has attracted many scientific researchers due to its flexibility, durability, and, most importantly, high electrical conductivity. However, the low dispensability and high curing temperature have hindered the use of graphene ink in many practical applications. In this work, graphene nanoplatelets (GNPs) were modified with oleic acid to improve dispensability. Then, the modified GNPs were employed as a major component in the conductive ink‘s formulation. The effects of the oleic acid, binder, and GNPs contents on the conductivity of the prepared ink were studied. The results showed that at the ink‘s formulation of 0.75 % binder and 6 % GNPs (modified with 2.5 % oleic acid), the lowest resistance with the value of 22 Ω.cm and sheet resistance of 7.56 Ω cm2 was obtained. Remarkably, the high conductivity of the modified conductive ink on the substrate could also be observed after curing at room temperature, which is advantageous for practical application. The viscosity of the resultant conductive ink could also be adjusted by changing the amount of solvent in the ink‘s formulation for application of the ink in the pen, painting, or inkjet printing. The graphene nanoplatelets were successfully modified with oleic acid to improve their dispensability in organic solvents. The modified GNPs were utilized as a main component fabrication of room temperature‐sintering conductive ink. The effects of the oleic acid, CAB binder, GNPs contents, and drying temperature on the conductivity of the ink were investigated in detail. The optimized compositions of the conductive ink was drawn with 0.75 % CAB and 6 % GNPs (modified with 2.5 % oleic acid). The prepared GNPs conductive ink could be fully aged at room temperature with line resistance of 22 Ω.cm and sheet resistance of 7.56 Ω cm2.
ISSN:2365-6549
2365-6549
DOI:10.1002/slct.202104249