Fabrication of Pt–Ag–Au heterogeneous truncated hollow sub-microspheres for chemically self-propelled colloidal motors

IF 2.5 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Yi Wei, Qian Zhao, Hongwen Zhang, Le Zhou, W. Cai
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引用次数: 1

Abstract

Colloidal motors with cavity structure, which have advantages over solid motors in catalytic efficiency, cargo capacity and biocompatibility, are still expected. Here, we design and fabricate a type of truncated hollow sub-microsphere via organic colloidal template etching/heating and layer-by-layer isotropic deposition. The as-prepared truncated hollow sphere is of one circular open pore through the shell layer and built of Pt, Ag and Au shell layers from inside to outside. They are controllable in sphere diameter, circular open pore size and shell thickness, which depend on the template and deposition conditions. Further experiments have shown that the Ag sandwich layer and post-deposition ageing process are crucial to obtaining strong and complete truncated hollow sub-microspheres. Their formation is attributed to the template geometry and nearly isotropic deposition. Due to the catalytic Pt layer on the inner surface and the truncated hollow spherical structure, such Pt–Ag–Au hollow spheres are demonstrated to be chemically propelled colloidal motors, which can directionally move in H2O2-containing solutions. This study presents a controllable route for mass-fabricating heterogeneous multi-layer truncated hollow sub-microspheres, and provides a new type of chemically self-propelled colloidal motor.
化学自推进胶体马达用Pt-Ag-Au非均相截断空心亚微球的制备
空腔结构的胶体马达在催化效率、载重量和生物相容性方面比固体马达具有优势,仍然值得期待。在这里,我们通过有机胶体模板蚀刻/加热和逐层各向同性沉积来设计和制备一种截顶中空亚微球。所制备的截头空心球是一个穿过壳层的圆形开孔,从内到外由Pt、Ag和Au壳层组成。它们在球体直径、圆形开孔尺寸和外壳厚度方面是可控的,这取决于模板和沉积条件。进一步的实验表明,Ag夹层和沉积后的老化过程对于获得坚固和完整的截短中空亚微球至关重要。它们的形成归因于模板几何形状和几乎各向同性的沉积。由于内表面的催化Pt层和截头空心球形结构,这种Pt–Ag–Au空心球被证明是化学推进的胶体马达,可以在含有H2O2的溶液中定向移动。本研究为大规模制备异质多层截头中空亚微球提供了一条可控的途径,并提供了一种新型的化学自推进胶体马达。
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来源期刊
Nano Futures
Nano Futures Chemistry-General Chemistry
CiteScore
4.30
自引率
0.00%
发文量
35
期刊介绍: Nano Futures mission is to reflect the diverse and multidisciplinary field of nanoscience and nanotechnology that now brings together researchers from across physics, chemistry, biomedicine, materials science, engineering and industry.
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