Ziyi Zhang, Corey Carlos, Derui Wang, Yutao Dong, Xudong Wang
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引用次数: 0
摘要
具有超大比表面积和独特电化学特性的超薄二维纳米材料被认为是清洁能源转换和环境应用领域极佳的电催化剂候选材料。然而,通过可扩展、可持续的工艺制备二维催化剂以满足工业需求仍具有挑战性。在此,我们报道了一种基于离子层外延的超薄二维纳米材料的简便循环合成方法。通过在溶液表面反复刷新表面活性剂单层,在环境条件下多次循环,从水面上获得了独立的 2.2 nm 厚的六边形 Co(OH)2 纳米片。这些纳米片始终表现出很高的 OER 性能,在 10 mA cm-2 条件下的平均过电位为 427.4 ± 5.3 mV。值得注意的是,六角形 NSs 可以从各种浓度的前驱体中获得,因此可以在相同的前驱体溶液中进行超过 84 个循环的合成。这将为二维纳米材料的自主设计和可持续合成提供启示,从而促进先进电催化技术的发展,迈向清洁的未来。
Sustainable and cyclic synthesis of 2D Co(OH)2 nanosheets for scalable production of high-performance electrocatalysts
Ultrathin 2D nanomaterials with extremely large surface area and unique electrochemical properties are considered excellent electrocatalyst candidates for clean energy conversion and environmental applications. However, it is still challenging to prepare 2D catalysts through a scalable and sustainable process that may become suitable for industrial demands. Here, we reported a facile cyclic synthesis method of ultrathin 2D nanomaterials based on the ionic layer epitaxy. By repeatedly refreshing a surfactant monolayer on the solution surface, free-standing 2.2 nm thick hexagonal Co(OH)2 nanosheets were obtained from the water surface at ambient conditions in multiple cycles. These nanosheets exhibited a consistently high OER performance with an average overpotential of 427.4 ± 5.3 mV at 10 mA cm−2. Remarkably, hexagonal NSs could be obtained from a wide range of precursor concentrations which could enable over 84 cycles of synthesis on the same stock precursor solution. It will shed light on the design of autonomous and sustainable synthesis of 2D nanomaterials for advanced electrocatalysis development toward a clean future.
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