posted on 2022-03-23, 11:29authored byWeihao Sun, Wuzong Zhou
Pseudo-icosahedral
Cu microcrystals have been synthesized in a
solvothermal system containing CuSO4·5H2O as the precursor, polyvinylpyrrolidone (PVP) as a reductant/capping
agent, and dimethylformamide as the solvent. The structural and morphological
evolutions over the reaction time are investigated, which enable us
to establish a novel formation mechanism of pseudo-icosahedral crystals
of Cu. The first crystalline phase that appeared in the solution is
Cu4SO4(OH)6·H2O in
the form of microflakes. The microflakes are reduced and decomposed
to Cu2O nanocrystallites, which assemble with PVP into
spherulites. The Cu2O crystals are further reduced to Cu
nanocrystallites, which aggregate with PVP again into spherical particles.
An extraordinary phenomenon is that 20 separated (111) triangular
plates form on each particle during surface recrystallization of Cu,
and their locations match to the final facets of the pseudo-icosahedron.
The plates extend to cover the whole surface of the sphere, forming
a pseudo-icosahedral shell, followed by extension of the recrystallization
from the surface to the core. This reversed crystal growth process
increases the thickness of the plates until all the Cu nanocrystallites
in the core are consumed. It is found that, during the surface recrystallization
of polycrystalline spheres, the particles preferentially select the
(111) planes of the face-centered cubic structure of Cu as the exposed
faces because these planes have the minimum surface binding energy.
The particles then try to keep as small as possible the specific surface
area, and a pseudo-icosahedral shape consisting of 20 (111) plates,
which has a specific surface area, about 10% lower than that of an
octahedron, formed by eight (111) plates. Accordingly, the overall
surface free energy of a pseudo-icosahedron is about 10% lower than
that of an octahedron. The formation of tetrahedra as building units
of icosahedra, as predicted previously, has not been observed. The
formation of ideal icosahedra, the so-called perfect Platonic solid,
and the formation of twin defects between neighboring (111) plates
are not possible. The newly proposed formation mechanism of pseudo-icosahedra
Cu sheds light on the understanding of formation of many other polyhedral
crystals.