Preparation of a Three-Dimensional Reduced Graphene Oxide Film by Using the Langmuir-Blodgett Method

Langmuir : the ACS Journal of Surfaces and Colloids
M Musoddiq JaafarP Vengadesh

Abstract

The Langmuir-Blodgett method has always been traditionally utilized in the deposition of two-dimensional structures. In this work, however, we employed the method to deposit three-dimensional reduced graphene oxide layers using an unconventional protocol for the first time. This was achieved by carrying out the dipping process after the collapse pressure or breaking point, which results in the formation of a highly porous three-dimensional surface topography. By varying the number of deposition layers, the porosity could be optimized from nanometer to micrometer dimensions. Employed as bioelectrodes, these three-dimensional reduced graphene oxide layers may allow improved adhesion and biocompatibility compared to the conventional two-dimensional surfaces. A larger number of pores also improves the mass transport of materials and therefore increases the charge-sustaining capacity and sensitivity. This could ultimately improve the performance of biofuel cells and other electrode-based systems.

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Citations

Jul 6, 2016·Small·Dan Wen, Alexander Eychmüller
Apr 27, 2018·Physical Chemistry Chemical Physics : PCCP·K RytelD Wróbel
Sep 14, 2017·Advanced Materials·Kostas KostarelosJose A Garrido
May 6, 2019·Sensors·Zahra Tavakolian-ArdakaniGiovanna Marrazza
Apr 6, 2018·Advanced Science·Zhongke YuanQuan Li
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Aug 28, 2020·Advances in Colloid and Interface Science·Michal BodikPeter Siffalovic
Nov 28, 2017·Langmuir : the ACS Journal of Surfaces and Colloids·Nurul ChotimahKatsumi Kaneko
Mar 7, 2019··Oksana ShinkarenkoEvgeny G. Glukhovskoy

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