Thermally stimulated structural evolution of bimetallic nanoplatelets - Changing from core-shell to alloyed to Janus nanoplatelets

IF 8.2 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Xiaobin Xie, Alfons van Blaaderen, Marijn A. van Huis
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引用次数: 0

Abstract

Gold-based bimetallic nanostructures exhibit unique optical and catalytic properties that are strongly dependent on their composition and nanoscale geometry. Here we show the nano-structural transformation of mesoporous-silica-coated Au-M (Ag, Pd, Pt) core-shell nanoplatelets (NPLs) with a triangular shape to alloyed platelets at temperatures at least 300 °C below the lowest melting point of the metals while still retaining the out-of-equilibrium triangular shape and intact mesoporous shell. Before the alloying started the rough core-shell morphology of the Au–Pd and Au–Pt NPL systems were first observed to relax into a much smoother core-shell morphology. The alloying temperature was found to be related to the melting points and atom fractions of the shell metals; the higher the melting point and atomic fraction of the shell metal, the higher the temperature required for alloying. The highest alloying temperature was found for the Au–Pt system (650 °C), which is still hundreds of degrees below the bulk melting points. Surprisingly, a phase separation of Au and Pt, and of Au and Pd, was observed at 1100 °C while both systems still had an anisotropic plate-like shape, which resulted in Janus-like morphologies where the pure Pt and pure Pd ended up on the tips of the NPLs as revealed via in-situ heating in the scanning transmission electron microscope (STEM). The Janus-type morphologies obtained at elevated temperatures for the NPLs composed of combinations of Au–Pt and Au–Pd, and the smooth core-shell morphologies before alloying, are very interesting for investigating how differences in the bi-metallic morphology affect plasmonic, catalytic and other properties.

双金属纳米片的热刺激结构演化--从核壳纳米片到合金纳米片再到 Janus 纳米片的变化
金基双金属纳米结构具有独特的光学和催化特性,这些特性与它们的组成和纳米级几何形状密切相关。在这里,我们展示了介孔二氧化硅包覆的 Au-M(Ag、Pd、Pt)核壳纳米小板(NPLs)的纳米结构转变,这种小板具有三角形,在低于金属最低熔点至少 300 °C 的温度下转变为合金小板,同时仍保留了失衡三角形和完整的介孔外壳。在合金化开始之前,首先观察到金-钯和金-铂 NPL 系统的粗糙核壳形态松弛成更为平滑的核壳形态。研究发现,合金化温度与外壳金属的熔点和原子分数有关;外壳金属的熔点和原子分数越高,合金化所需的温度就越高。金-铂体系的合金化温度最高(650 °C),但仍比主体熔点低几百度。令人惊讶的是,在 1100 °C时观察到金与铂以及金与钯的相分离,而这两种体系仍然具有各向异性的板状形状,这就形成了杰纳斯型形态,通过扫描透射电子显微镜(STEM)中的原位加热,纯铂和纯钯最终出现在 NPL 的顶端。由金-铂和金-钯组合而成的 NPL 在高温下获得的 Janus 型形貌,以及合金化前的光滑核壳形貌,对于研究双金属形貌的差异如何影响等离子体、催化和其他性能非常有意义。
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来源期刊
CiteScore
11.30
自引率
3.90%
发文量
130
审稿时长
31 days
期刊介绍: Materials Today Nano is a multidisciplinary journal dedicated to nanoscience and nanotechnology. The journal aims to showcase the latest advances in nanoscience and provide a platform for discussing new concepts and applications. With rigorous peer review, rapid decisions, and high visibility, Materials Today Nano offers authors the opportunity to publish comprehensive articles, short communications, and reviews on a wide range of topics in nanoscience. The editors welcome comprehensive articles, short communications and reviews on topics including but not limited to: Nanoscale synthesis and assembly Nanoscale characterization Nanoscale fabrication Nanoelectronics and molecular electronics Nanomedicine Nanomechanics Nanosensors Nanophotonics Nanocomposites
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