Ligand Exchange Governs the Crystal Structures in
Binary Nanocrystal Superlattices
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Abstract
The
surface chemistry in colloidal nanocrystals on the final crystalline
structure of binary superlattices produced by self-assembly of two
sets of nanocrystals is hereby demonstrated. By mixing nanocrystals
having two different sizes and the same coating agent, oleylamine
(OAM), the binary nanocrystal superlattices that are produced, such
as NaCl, AlB<sub>2</sub>, NaZn<sub>13</sub>, and MgZn<sub>2</sub>,
are well in agreement with the crystalline structures predicted by
the hard-sphere model, their formation being purely driven by entropic
forces. By opposition, when large and small nanocrystals are coated
with two different ligands [OAM and dodecanethiol (DDT), respectively]
while keeping all other experimental conditions unchanged, the final
binary structures markedly change and various structures with lower
packing densities, such as Cu<sub>3</sub>Au, CaB<sub>6</sub>, and
quasicrystals, are observed. This effect of the nanocrystals’
coating agents could also be extended to other binary systems, such
as Ag–Au and CoFe<sub>2</sub>O<sub>4</sub>–Ag supracrystalline
binary lattices. In order to understand this effect, a mechanism based
on ligand exchange process is proposed. Ligand exchange mechanism
is believed to affect the thermodynamics in the formation of binary
systems composed of two sets of nanocrystals with different sizes
and bearing two different coating agents. Hence, the formation of
binary superlattices with lower packing densities may be favored kinetically
because the required energetic penalty is smaller than that of a denser
structure