Oleylamine (OLA) is a ubiquitous
organic ligand used in the synthesis
of inorganic nanocrystals (NCs) due to its ability to reduce metal
precursors and sterically stabilize NCs. However, attempts to thermally
remove the ligand from deposited OLA-capped NC films result in ligand
pyrolysis, where the organic residue is ultimately embedded into the
active material as a carbon defect. Herein, we investigated the thermal
decomposition and restructuring of OLA ligands using a combination
of Raman spectroscopy and X-ray photoelectron spectroscopy (XPS),
seeking to determine the specific nature of OLA’s decomposition
and reasons for its ultimate incorporation into a carbon-rich fine-grain
layer observed in Cu2ZnSn(S1–x
Se
x
)4 (CZTSSe) systems.
While it has historically been expected that OLA pyrolyzes during
thermal treatments, this work identifies that OLA decomposes into
nanostructured graphitic carbon, which is first detectable immediately
after the NC synthesis at 225 °C, well before the employment
of thermal treatments. These graphitic flakes are further identified
as disordered graphene oxide, which segregates from OLA-capped NCs
during deposition to assemble into the carbon-rich layer. In identifying
that the carbon-rich fine-grain layer originates prior to thermal
treatments, we introduce a strategy to partially reduce the presence
of this layer by isolating the graphene oxide flakes immediately after
the CZTS NC synthesis.
Inorganic–organic interfaces: a tutorial on using organic functional groups to enhance the performances and/or enable new functionality of inorganic nanomaterials.
Aliphatic amine and carboxylic acid ligands are widely
used as
organic solvents during the bottom-up synthesis of inorganic nanoparticles
(NPs). Although the ligands’ ability to alter final NP properties
has been widely studied, side reactivity of these ligands is emerging
as an important mechanism to consider. In this work, we study the
thermal decomposition of common ligands with varying functional groups
(amines and carboxylic acids) and bond saturations (from saturated
to polyunsaturated). Here, we investigate how these ligand properties
influence decomposition in the absence and presence of precursors
used in NP synthesis. We show that during the synthesis of inorganic
chalcogenide NPs (Cu
2
ZnSnS
4
, Cu
x
S, and SnS
x
) with metal
acetylacetonate precursors and elemental sulfur, the ligand pyrolyzes,
producing alkylated graphitic species. Additionally, there was less
to no ligand decomposition observed during the sulfur-free synthesis
of ZnO and CuO with metal acetylacetonate precursors. These results
will help guide ligand selection for NP syntheses and improve reaction
purity, an important factor in many applications.
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