Mixed-metal
chalcohalide semiconductors have emerged as promising
candidates for photovoltaic applications. However, preparation of
these multinary compounds using solution-phase techniques remains
particularly challenging compared to traditional solid-state methods.
To fully harness their potential, it is desirable to develop synthetic
methods that enable control over both the phase purity and dimensionality
of chalcohalides. Here, we report the solution-phase synthesis of
Pb2SbS2I3 and Pb2BiS2I3 quaternary chalcohalides using readily available
precursors. Fine tuning of reaction parameters allows for the isolation
of rod-like morphologies with tunable diameters and aspect ratios.
The quaternary chalcohalides display photoluminescence as an ensemble
as well as at the single particle level, as demonstrated using fluorescence
microscopy. We further evaluate the relative stability and band gap
of Pb2SbS2I3 polymorphs and their
coloring patterns using electronic structure calculations. The synthetic
methods developed here will motivate the study of ever more complex
chalcohalides and other multinary semiconductors for new technological
applications.
Increasing demand for effective energy conversion materials
and
devices has renewed interest in semiconductors comprised of earth-abundant
and biocompatible elements. Alkaline-earth sulfides doped with rare
earth ions are versatile optical materials. However, relatively little
is known about controlling the dimensionality, surface chemistry,
and inherent optical properties of the undoped versions of alkaline-earth
mono- and polychalcogenides. We describe the colloidal synthesis of
alkaline-earth chalcogenide nanocrystals through the reaction of metal
carboxylates with carbon disulfide or selenourea. Systematic exploration
of the synthetic phase space allows us to tune particle sizes over
a wide range using a mixture of commercially available carboxylate
precursors. Solid-state NMR spectroscopy confirms the phase purity
of the selenide compositions. Surface characterization reveals that
bridging carboxylates and amines preferentially terminate the surface
of the nanocrystals. While these materials are colloidally stable
in the mother solution, the selenides are susceptible to oxidation
over time, eventually degrading to selenium metal through polyselenide
intermediates. As part of these investigations, we have developed
the colloidal syntheses of barium di- and triselenides, two among
few reported nanocrystalline alkaline-earth polychalcogenides. Electronic
structure calculations reveal that both materials are indirect band
gap semiconductors. The colloidal chemistry presented here may enable
the synthesis of more complex, multinary chalcogenide materials containing
alkaline-earth elements.
A highly efficient luminescent solar concentrator (LSC) comprised of nanosized metal-cluster as molecular luminophores anchored within a poly (methyl methacrylate) (PMMA) was fabricated through a simple solution process. Organic-inorganic salts...
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