Zernike Institute for Advanced Materials, University of Groningen, Nijenborgh 4, 9747 AG Groningen, The Netherlands.
Nanoscale. 2017 Jun 22;9(24):8149-8156. doi: 10.1039/c7nr00916j.
In this work we report strategies to nucleate bimetallic nanoparticles (NPs) made by gas phase synthesis of elements showing difficulty in homogeneous nucleation. It is shown that the nucleation assisted problem of bimetallic NP synthesis can be solved via the following pathways: (i) selecting an element which can itself nucleate and act as a nucleation center for the synthesis of bimetallic NPs; (ii) introducing H or CH as an impurity/trace gas to initiate nucleation during the synthesis of bimetallic NPs. The latter can solve the problem if none of the elements in a bimetallic NP can initiate nucleation. We illustrate the abovementioned strategies for the case of Mg based bimetallic NPs, which are interesting as hydrogen storage materials and exhibit both nucleation and oxidation issues even under ultra-high vacuum conditions. In particular, it is shown that adding H in small proportions favors the formation of a solid solution/alloy structure even in the case of immiscible Mg and Ti, where normally phase separation occurs during synthesis. In addition, we illustrate the possibility of improving the nucleation rate, and controlling the structure and size distribution of bimetallic NPs using H/CH as a reactive/nucleating gas. This is shown to be associated with the dimer bond energies of the various formed species and the vapor pressures of the metals, which are key factors for NP nucleation.
在这项工作中,我们报告了通过气相合成元素来成核双金属纳米粒子(NPs)的策略,这些元素在均匀成核方面存在困难。结果表明,通过以下途径可以解决双金属 NP 合成的成核辅助问题:(i)选择本身可以成核并作为双金属 NPs 合成的成核中心的元素;(ii)引入 H 或 CH 作为杂质/痕量气体,在双金属 NPs 的合成过程中引发成核。如果双金属 NP 中的任何元素都不能引发成核,后者可以解决这个问题。我们以基于 Mg 的双金属 NPs 为例说明了上述策略,这些 NPs 作为储氢材料很有趣,即使在超高真空条件下,它们也存在成核和氧化问题。特别是,结果表明,即使在 Mg 和 Ti 不相容的情况下,少量添加 H 也有利于形成固溶体/合金结构,因为在合成过程中通常会发生相分离。此外,我们说明了使用 H/CH 作为反应/成核气体来提高成核速率和控制双金属 NPs 的结构和尺寸分布的可能性。这与各种形成物种的二聚体键能以及金属的蒸气压有关,这些是 NP 成核的关键因素。
