Abstract
This review describes some principles of the controlled synthesis of metal nanoparticles, focusing on how the fundamental understanding of their synthesis in the solution-phase can be put to tailor size, shape, composition, and architecture. The maneuvering over these parameters not only enable the tuning of properties, but also the maximization and optimization of performances for various applications. Herein, we start with a brief description of metallic nanoparticles, highlighting the motivation for achieving physicochemical control in their synthesis. After that, we turn our attention to some important definitions and classifications as well as their unique properties such as surface and quantum effects. Moreover, we discuss the strategies for the controlled synthesis of metal nanomaterials based on the top-down and bottom-up approaches, focusing our discussion on their formation mechanisms in liquid-phase in terms of both thermodynamic and kinetic control. Finally, we point out the promising applications of controlled nanomaterials in the field of nanocatalysis and plasmon-enhanced catalysis, describing some of the current challenges in these fields.
Highlights
Among the several classes of materials, noble metals such as silver (Ag) and gold (Au) have fascinated humanity for centuries since their discovery (Eustis and El-Sayed 2006)
This review summarized the definitions, recent studies, and challenges involved in the controlled synthesis of noble metal nanoparticles
It is clear that the literature concerning the controlled synthesis of metal nanomaterials continues to expand
Summary
Among the several classes of materials, noble metals such as silver (Ag) and gold (Au) have fascinated humanity for centuries since their discovery (Eustis and El-Sayed 2006). The galvanic replacement reaction is especially interesting as it allows us to control the sizes, shapes, compositions and internal structures, leading to the formation of nanomaterials displaying a high surface to volume ratio and large pore volume (Xia et al 2013, da Silva et al 2017).
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