Instituto Nacional del Carbón, INCAR-CSIC , Apartado 73, 33080 Oviedo, Spain.
Laboratório de Processos de Separação e Reacção, Laboratório de Catálise e Materiais (LSRE-LCM), Departamento de Engenharia Química, Faculdade de Engenharia, Universidade do Porto , R. Dr. Roberto Frias s/n, 4200-465 Porto, Portugal.
ACS Appl Mater Interfaces. 2017 Jul 19;9(28):24085-24099. doi: 10.1021/acsami.7b04802. Epub 2017 Jul 5.
Graphene and graphene-based materials have shown great promise in many technological applications, but their large-scale production and processing by simple and cost-effective means still constitute significant issues in the path of their widespread implementation. Here, we investigate a straightforward method for the preparation of a ready-to-use and low oxygen content graphene material that is based on electrochemical (anodic) delamination of graphite in aqueous medium with sodium halides as the electrolyte. Contrary to previous conflicting reports on the ability of halide anions to act as efficient exfoliating electrolytes in electrochemical graphene exfoliation, we show that proper choice of both graphite electrode (e.g., graphite foil) and sodium halide concentration readily leads to the generation of large quantities of single-/few-layer graphene nanosheets possessing a degree of oxidation (O/C ratio down to ∼0.06) lower than that typical of anodically exfoliated graphenes obtained with commonly used electrolytes. The halide anions are thought to play a role in mitigating the oxidation of the graphene lattice during exfoliation, which is also discussed and rationalized. The as-exfoliated graphene materials exhibited a three-dimensional morphology that was suitable for their practical use without the need to resort to any kind of postproduction processing. When tested as dye adsorbents, they outperformed many previously reported graphene-based materials (e.g., they adsorbed ∼920 mg g for methyl orange) and were useful sorbents for oils and nonpolar organic solvents. Supercapacitor cells assembled directly from the as-exfoliated products delivered energy and power density values (up to 15.3 Wh kg and 3220 W kg, respectively) competitive with those of many other graphene-based devices but with the additional advantage of extreme simplicity of preparation.
石墨烯和基于石墨烯的材料在许多技术应用中显示出巨大的潜力,但它们的大规模生产和通过简单且具有成本效益的方法进行加工仍然是广泛应用的重大问题。在这里,我们研究了一种简单的方法,用于制备基于电化学(阳极)剥离的即用型低含氧量石墨烯材料,该方法使用水基中的卤化物作为电解质来剥离石墨。与之前关于卤化物阴离子作为电化学石墨烯剥离中有效剥离电解质的能力的相互矛盾的报告相反,我们表明,适当选择石墨电极(例如石墨箔)和卤化钠浓度可以很容易地生成大量具有较低氧化度(O/C 比低至约 0.06)的单层/少层石墨烯纳米片,其氧化度低于通常使用的电解质获得的阳极剥离石墨烯的典型氧化度。卤化物阴离子被认为在剥离过程中减轻了石墨烯晶格的氧化,这也进行了讨论和合理化。剥离得到的石墨烯材料具有三维形态,适用于实际应用,无需进行任何后生产处理。当用作染料吸附剂时,它们的性能优于许多以前报道的基于石墨烯的材料(例如,它们对甲基橙的吸附量约为 920mg g),并且是油和非极性有机溶剂的有用吸附剂。直接由剥离产物组装的超级电容器电池的能量和功率密度值(分别高达 15.3 Wh kg 和 3220 W kg)与许多其他基于石墨烯的器件相当,但具有制备极其简单的额外优势。
