Abstract
Graphene oxide (GO) can be defined as a single monolayer of graphite with oxygen-containing functionalities such as epoxides, alcohols, and carboxylic acids. It is an interesting alternative to graphene for many applications due to its exceptional properties and feasibility of functionalization. In this study, electrochemically exfoliated graphene oxides (EGOs) with different amounts of surface groups, hence level of oxidation, were prepared by an electrochemical two-stage approach using graphite as raw material. A complete characterization of the EGOs was carried out in order to correlate their surface topography, interlayer spacing, defect content, and specific surface area (SSA) with their electrical, thermal, and mechanical properties. It has been found that the SSA has a direct relationship with the d-spacing. The EGOs electrical resistance decreases with increasing SSA while rises with increasing the D/G band intensity ratio in the Raman spectra, hence the defect content. Their thermal stability under both nitrogen and dry air atmospheres depends on both their oxidation level and defect content. Their macroscopic mechanical properties, namely the Young’s modulus and tensile strength, are influenced by the defect content, while no correlation was found with their SSA or interlayer spacing. Young moduli values as high as 54 GPa have been measured, which corroborates that the developed method preserves the integrity of the graphene flakes. Understanding the structure-property relationships in these materials is useful for the design of modified GOs with controllable morphologies and properties for a wide range of applications in electrical/electronic devices.
Highlights
Considerable interest has been directed to graphene (G) and its derivatives including graphene oxide (GO)
The experimental conditions set for the synthesis process are essential, since they modify a number of physical properties including interlayer distance, specific surface area (SSA), defect content, and so forth
In a previous study [37], we reported a novel, straightforward, green, and inexpensive two-stage approach for the synthesis of electrochemically exfoliated graphene oxides (EGOs) that allows to finely control the level of GO oxidation and exfoliation by carefully modifying the synthesis conditions
Summary
Considerable interest has been directed to graphene (G) and its derivatives including graphene oxide (GO). It is possible to prepare novel thin films and flexible composites at a cheaper cost compared to other carbon-based nanomaterials [9,10]. These materials can be used as fillers in polymer matrices due to their 2D lamellar structure, very high specific surface area (SSA), and their nature to disperse in a wide range of organic and inorganic solvents [11,12,13,14]. The experimental conditions set for the synthesis process are essential, since they modify a number of physical properties including interlayer distance, specific surface area (SSA), defect content, and so forth. The heat capacity, thermal conductivity, and specific capacitance can be modified via tailoring the level of oxidation [24]
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