Nowadays, research on electrochemical storage systems moves into the direction of post-lithium-ion batteries, such as aluminum-ion batteries, and the exploration of suitable materials for such batteries. Vanadium pentoxide (V O ) is one of the most promising host materials for the intercalation of multivalent ions. Here, we report on the fabrication of a binder-free and self-supporting V O micrometer-thick paper-like electrode material and its use as the cathode for rechargeable aluminum-ion batteries. The electrical conductivity of the cathode was significantly improved by a novel in-situ and self-limiting copper migration approach into the V O structure. This process takes advantage of the dissolution of Cu by the ionic liquid-based electrolyte, as well as the presence of two different accommodation sites in the nanostructured V O available for aluminum-ions and the migrated Cu. Furthermore, the advanced nanostructured cathode delivered a specific discharge capacity of up to ~170 mAh g and the reversible intercalation of Al for more than 500 cycles with a high Coulomb efficiency reaching nearly 100%. The binder-free concept results in an energy density of 74 Wh kg , which shows improved energy density in comparison to the so far published V O -based cathodes. Our results provide valuable insights for the future design and development of novel binder-free and self-supporting electrodes for rechargeable multivalent metal-ion batteries associating a high energy density, cycling stability, safety and low cost.
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机译:如今,对电化学存储系统的研究已朝后锂离子电池(如铝离子电池)的方向发展,并探索了用于此类电池的合适材料。五氧化二钒(V O)是最有希望插入多价离子的主体材料之一。在这里,我们报告了无粘结剂,自支撑的V O微米厚纸样电极材料的制备及其作为可充电铝离子电池阴极的用途。阴极的电导率通过新颖的原位自限铜迁移至V O结构而得到显着改善。该过程利用了离子液体基电解质对铜的溶解作用,以及在纳米结构的V O中可用于铝离子和迁移的Cu的两个不同的容纳位点。此外,先进的纳米结构阴极可提供高达〜170 mAh g的比放电容量,并且Al可逆插层超过500个循环,并且具有高达100%的高库仑效率。不含粘合剂的概念产生74 Wh kg kg的能量密度,与迄今为止公开的基于V O的阴极相比,能量密度得到改善。我们的结果为未来可充电多价金属离子电池的新型无粘结剂自支撑电极的设计和开发提供了宝贵的见识,这些电极结合了高能量密度,循环稳定性,安全性和低成本。
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