Here, large-scale and uniform hexagonal zinc oxide (ZnO) nanosheet films were deposited onto indium tin oxide (ITO)-coated transparent conducting glass substrates via a facile galvanic displacement deposition process. Compared with other commonly used solution methods, this process avoids high temperature and electric power as well as supporting agents to make it simple and cost-effective. The as-fabricated ZnO nanosheet films have uniform hexagonal wurtzite structure. The photoelectrochemical (PEC) cell based on ZnO nanosheet film/ITO photoelectrode was also fabricated and its performance was improved by optimizing the solution concentration. A higher photocurrent density of ~500?μA?cm~(?2) under AM 1.5?G simulated illumination of 100?mW?cm~(?2) with zero bias potential (vs. Ag/AgCl electrode) was obtained, which may ascribe to the increased surface-to-volume ratio of disordered ZnO nanosheet arrays. Our developed method may be used to deposit other oxide semiconductors, and the ZnO nanosheet film/ITO PEC cell can be used to design low-cost optoelectronic and photoelectrochemical devices.
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机译:在这里,大规模和均匀的六边形氧化锌(ZnO)纳米片薄膜通过便捷的电位移沉积工艺沉积到涂有铟锡氧化物(ITO)的透明导电玻璃基板上。与其他常用的解决方法相比,此过程避免了高温,高功率以及辅助剂的使用,从而使其变得简单且具有成本效益。制成的ZnO纳米片薄膜具有均匀的六角纤锌矿结构。还制备了基于ZnO纳米片薄膜/ ITO光电极的光电化学电池,并通过优化溶液浓度来提高其性能。在具有零偏置电势(相对于Ag / AgCl电极)的100μmW?cm〜(?2)的AM 1.5?G模拟照明下,获得了更高的光电流密度〜500?μA?cm〜(?2),可能归因于无序ZnO纳米片阵列的表面体积比增加。我们开发的方法可用于沉积其他氧化物半导体,而ZnO纳米片薄膜/ ITO PEC电池可用于设计低成本的光电和光电化学器件。
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