Large-scale Production of Few-Layer Reduced Graphene Oxide by the Rapid Thermal Reduction of Graphene Oxide and Its Structural Characterization

Osman Eksik
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Abstract

Graphene, a carbon allotrope, is a two-dimensional honeycomb of carbon atoms. Although graphene is a thin material, it is the strongest material known on Earth thanks to the strong carbon bonds in its structure. It is stated that the strength of these carbon bonds in graphene is about 100 times stronger than steel. In this study, graphite was first converted into graphene oxide (GO) by the Improved Hummers method, which is one of the methods suitable for large-scale production. Reduced graphene oxide (RGO) was obtained from the synthesized GOs by thermal reduction. TGA, FTIR, XRD, XPS, Raman, BET, and SEM analyses were used to characterize GO produced using the improved Hummers method and RGO reduced by thermal methods. TGA measurements show that RGO produced using the thermal approach had a lower mass loss than graphite oxidized using the improved Hummers process. This shows that the GO sample prepared using the improved Hummers approach contains a considerable number of distinct oxygen-containing groups. The novelty of the modified Hummers' method lies in its enhanced efficiency in producing graphene oxide through reduced thermal reaction times and improved scalability compared to the original approach in the literature. The C:O ratio of the GO and RGO samples was determined by XPS to be 1.88 and 11.17, respectively. The ID/IG ratio obtained by Raman analysis was 0.973. In addition, RGO's BET surface area was discovered to be 543.6 m2 g-1. These findings demonstrated that graphite was successfully oxidized by an improved Hummers method, and the resulting GO was thermally converted to few-layer RGO.
通过快速热还原大规模制备少层还原氧化石墨烯及其结构表征
石墨烯是一种碳同素异形体,是由碳原子组成的二维蜂窝状结构。虽然石墨烯是一种很薄的材料,但由于其结构中的强碳键,它是地球上已知的最坚固的材料。据说,石墨烯中这些碳键的强度大约是钢的 100 倍。在这项研究中,石墨首先通过改良 Hummers 法转化为氧化石墨烯(GO),这是适合大规模生产的方法之一。还原氧化石墨烯(RGO)通过热还原法从合成的 GO 中获得。使用 TGA、傅立叶变换红外光谱、XRD、XPS、拉曼光谱、BET 和扫描电镜分析了使用改进 Hummers 法生产的 GO 和通过热法还原的 RGO 的特性。TGA 测量结果表明,与使用改进的 Hummers 工艺氧化的石墨相比,使用热法生产的 RGO 的质量损失更低。这表明使用改进的 Hummers 方法制备的 GO 样品含有相当多的不同含氧基团。与文献中的原始方法相比,改进型 Hummers 方法的新颖之处在于通过缩短热反应时间和提高可扩展性提高了生产氧化石墨烯的效率。通过 XPS 测定,GO 和 RGO 样品的 C:O 比率分别为 1.88 和 11.17。拉曼分析得出的 ID/IG 比率为 0.973。此外,还发现 RGO 的 BET 表面积为 543.6 平方米 g-1。这些研究结果表明,通过改进的 Hummers 方法成功地氧化了石墨,并将生成的 GO 热转化成了少层 RGO。
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