A Simple Approach for Preparing Transparent Conductive Graphene Films Using the Controlled Chemical Reduction of Exfoliated Graphene Oxide in an Aqueous Suspension
Citations Over TimeTop 10% of 2010 papers
Abstract
We report a simple method for preparing transparent conductive graphene films using a chemically converted graphene (CCG) suspension that was obtained via controlled chemical reduction of exfoliated graphene oxide (GO) in the absence of dispersants. Upon thermal annealing of the CCG films, the films displayed a sheet resistance on the order of 103 Ω·◻−1 at 80% transparency (550 nm), with a bulk conductivity on the order of 102 S·cm−1. FT-IR, UV−visible, and X-ray photoelectron spectroscopy results showed that the combination of the controlled reduction of GO in suspension and thermal annealing of the CCG films efficiently restored the sp2 carbon networks of the graphene sheets, facilitating charge carrier transport in the individual CCG sheets. Furthermore, grazing-incidence X-ray diffraction results showed that the thermal annealing of the CCG films reduced the interlayer distance between the CCG sheets to a distance comparable to that in bulk graphite, facilitating charge carrier transport across the CCG sheets. Polymer solar cell devices composed of the CCG films as transparent electrodes showed power conversion efficiencies, η, of 1.01 ± 0.05%, which corresponded to half the value (2.04 ± 0.1%) of the reference devices, in which indium tin oxide-covered glass was used for the transparent electrode.
Related Papers
- → Sheet resistance dependence of fluorine-doped tin oxide films for high-performance electrochromic devices(2018)51 cited
- → Electro-optical properties of spray deposited fluorine doped tin oxide thin films for solar cell applications(2020)1 cited
- Preparation and Characterization of Graphene(2010)
- → A new method to exfoliate Graphite oxide and application for synthesis Graphene by chemical method(2014)
- Effect of dopant concentration and deposition time on the properties of fluorine-doped tin oxide (FTO) film deposited via spray pyrolysis(2012)