Smajic Jasmin, Alazmi Amira, Batra Nitinkumar, Palanisamy Tamilarasan, Anjum Dalaver H, Costa Pedro M F J
Physical Science and Engineering Division, King Abdullah University of Science and Technology, Thuwal, 23955-6900, Saudi Arabia.
King Abdullah University of Science and Technology, Core Labs, Thuwal, 23955-6900, Saudi Arabia.
Small. 2018 Dec;14(51):e1803584. doi: 10.1002/smll.201803584. Epub 2018 Oct 25.
Research in the field of aluminum batteries has focused heavily on electrodes made of carbonaceous materials. Still, the capacities reported for these multivalent systems remain stubbornly low. It is believed that a high structural quality of graphitic carbons and/or specific surface areas of >1000 m g are key factors to obtain optimal performance and cycling stability. Here an aluminum chloride battery is presented in which reduced graphene oxide (RGO) powder, dried under supercritical conditions, is used as the active cathode material and niobium foil as the current collector. With a specific surface area of just 364 m g , the RGO enables a gravimetric capacity of 171 mAh g at 100 mA g and remarkable stability over a wide range of current densities (<15% decrease over 100 cycles in the interval 100-20000 mA g ). These properties, up to now achieved only with much larger surface area materials, result from the cathode's tailored mesoporosity. The 20 nm wide mesopores facilitate the movement of the chloroaluminate ions through the RGO, effectively minimizing the inactive mass content of the electrode. This more than compensates for the ordinary micropore volume of the graphene powder.
铝电池领域的研究主要集中在由碳质材料制成的电极上。然而,这些多价体系所报道的容量仍然很低。据信,石墨碳的高结构质量和/或比表面积大于1000 m²/g是获得最佳性能和循环稳定性的关键因素。本文展示了一种氯化铝电池,其中在超临界条件下干燥的还原氧化石墨烯(RGO)粉末被用作活性阴极材料,铌箔用作集流体。RGO的比表面积仅为364 m²/g,在100 mA/g的电流密度下,其重量容量为171 mAh/g,并且在很宽的电流密度范围内具有显著的稳定性(在100 - 20000 mA/g的区间内,100次循环后容量下降小于15%)。这些迄今为止仅在比表面积大得多的材料上才能实现的性能,源于阴极定制的介孔结构。20纳米宽的介孔促进了氯铝酸盐离子在RGO中的移动,有效地减少了电极中无活性物质的含量。这足以弥补石墨烯粉末普通的微孔体积。
