Solution Chemistry of Self-Assembled Graphene Nanohybrids for High-Performance Flexible Biosensors

Authors
Choi, Bong GillPark, HoSeokPark, Tae JungYang, Min HoKim, Joon SungJang, Sung-YeonHeo, Nam SuLee, Sang YupKong, JingHong, Won Hi
Issue Date
2010-05
Publisher
AMER CHEMICAL SOC
Citation
ACS NANO, v.4, no.5, pp.2910 - 2918
Abstract
We report the preparation of free-standing flexible conductive reduced graphene oxide/Nafion (RGON) hybrid films by a solution chemistry that utilizes self-assembly and directional convective-assembly. The hydrophobic backbone of Nafion provided well-defined integrated structures, on micro- and macroscales, for the construction of hybrid materials through self-assembly, while the hydrophilic sulfonate groups enabled highly stable dispersibility (similar to 0.5 mg/mL) and long-term stability (2 months) for graphene. The geometrically interlocked morphology of RGON produced a high degree of mechanical integrity in the hybrid films, while the interpenetrating network constructed favorable conduction pathways for charge transport. Importantly, the synergistic electrochemical characteristics of RGON were attributed to high conductivity (1176 S/m), facilitated electron transfer (ET), and low interfacial resistance. Consequently, RGON films obtained the excellent figure of merit as electrochemical biosensing platforms for organophosphate (OP) detection, that is, a sensitivity of 10.7 nA/mu M, detection limit of 1.37 x 10(-7) M, and response time of <3 s. In addition, the reliability of RGON biosensors was confirmed by a fatigue test of 100 bending cycles. The strategy described here provides insight into the fabrication of graphene and hybrid nanomaterials from a material perspective, as well as the design of biosensor platforms for practical device applications.
Keywords
WALLED CARBON NANOTUBES; IONIC LIQUID; NAFION; FILMS; TRANSPARENT; DISPERSION; SHEETS; WALLED CARBON NANOTUBES; IONIC LIQUID; NAFION; FILMS; TRANSPARENT; DISPERSION; SHEETS; graphene nanohybrid; self-assembly; functionalization; flexible electronics; biosensor
ISSN
1936-0851
URI
https://pubs.kist.re.kr/handle/201004/131512
DOI
10.1021/nn100145x
Appears in Collections:
KIST Article > 2010
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