过度生长与电偶置换：钯种子在钯-铂沉积过程中的作用机制

Overgrowth Versus Galvanic Replacement: Mechanistic Roles of Pd Seeds during the Deposition of Pd-Pt.

作者信息

Ataee-Esfahani Hamed, Koczkur Kallum M, Weiner Rebecca G, Skrabalak Sara E

机构信息

Department of Chemistry, Indiana University Bloomington, 800 E. Kirkwood Avenue, Bloomington, Indiana 47405, United States.

出版信息

ACS Omega. 2018 Apr 9;3(4):3952-3956. doi: 10.1021/acsomega.8b00394. eCollection 2018 Apr 30.

DOI:10.1021/acsomega.8b00394

PMID:31458632

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6641295/

Abstract

Here, a systematic study of the roles played by Pd seeds during seed-mediated coreduction of Pd-Pt is presented. Either nanoparticles with porous, hollow architectures or concave nanocubes were achieved, depending on whether the synthesis conditions favored galvanic replacement or overgrowth. Prior works have shown that the galvanic replacement reaction between seeds and a precursor can be suppressed by introducing a faster, parallel reaction that removes one of the reagents (e.g., adatom generation in solution rather than surface-catalyzed precursor reduction). Here, we show that the galvanic replacement reaction depends on the size and concentration of the Pd seeds; the former of which can be manipulated during the course of the reaction through the use of a secondary reducing agent. This insight will guide future syntheses of multimetallic nanostructures by seeded methods, allowing for a range of nanocrystals to be precisely engineered for a variety of applications.

摘要

本文展示了对钯种子在钯-铂种子介导的共还原过程中所起作用的系统研究。根据合成条件有利于电化置换还是过度生长，可得到具有多孔、中空结构的纳米颗粒或凹面纳米立方体。先前的研究表明，通过引入更快的平行反应以去除其中一种试剂（例如，溶液中吸附原子的生成而非表面催化的前驱体还原），可以抑制种子与前驱体之间的电化置换反应。在此，我们表明电化置换反应取决于钯种子的尺寸和浓度；其中前者可在反应过程中通过使用二次还原剂进行调控。这一见解将指导未来通过种子法合成多金属纳米结构，从而能够为各种应用精确设计一系列纳米晶体。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7036/6641295/b692ce98eabd/ao-2018-003947_0001.jpg

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过度生长与电偶置换：钯种子在钯-铂沉积过程中的作用机制

Overgrowth Versus Galvanic Replacement: Mechanistic Roles of Pd Seeds during the Deposition of Pd-Pt.

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