Serial Morphological Transformations of Au Nanocrystals
via Post-Synthetic Galvanic Dissolution and Recursive Growth
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Abstract
Geometric
modification of Au nanostructures is typically achieved
in multistep reactions, where synthesis parameters need to be well-controlled.
In this work, we report a facile method using IrCl<sub>3</sub> to
refine morphologically diverse Au nanostructures and trigger their
morphological transformations. The synthesis is accomplished at room
temperature by an iterative process of galvanic dissolution and recursive
growth. Seeds retrieved after the dissolution of different Au nanostructure
archetypes served in the structural recovery and morphological transformation
via rapid and slow regrowth, respectively. The rapid regrowth was
accomplished by adding ascorbic acid (AA), while the slow regrowth
occurred spontaneously. In the structural recovery, the nanostructures
regrew back to their original morphologies. Improvements in the shape
quality and size distributions were observed for the rapid regrowth
case. In the spontaneous slow regrowth transformation, the resulting
nanostructures were encased by {111} facets, minimizing total surface
energy through the more closely packed planes. Transformation of the
four nanostructure archetypes showed correlation, trending toward
these lower indexed facets and to twinned structures (from RDs to
OCTs, OCTs to TPs, and TPs to PSs). Surveying all observations, our
work of the metal cation-mediated geometric modulation of Au nanostructures
delivers important clues in understanding nanoparticle synthesis and
provides a new path for the fabrication of nanocrystals with high-quality
size and shape distribution