Nanoscale assembly of ultrasmall metal nanoclusters (MNCs) by means of molecular forces has proven to be a powerful strategy to engineer their molecule-like properties in multiscale dimensions. By leveraging depletion attraction as the guiding force, herein, we demonstrate the formation of kinetically trapped NCs assemblies with enhanced photoluminescence (PL) and excited state lifetimes and extend the principle to cluster impregnated cationic nanogels, nonluminescent Au(I)−thiolate complexes, and weakly luminescent CuNCs. We further demonstrate a thermal energy driven kinetic barrier breaking process to isolate these assemblies. These isolated assemblies are thermodynamically stable, built from a strong network among several discrete, ultrasmall AuNCs and exhibit several unusual properties such as high stability in various pH, strong PL, microsecond lifetimes, large Stocks shifts, and higher accumulation in the lysosome of cancer cells. We anticipate our strategy may find wider use in creating a large variety of MNC-based assemblies with many unforeseen arrangements, properties, and applications.
Functional
superstructures constructed from metal nanoclusters
(MNCs) hold great promise in providing highly tunable photoluminescence
(PL), catalytic activity, photothermal stability, and biological functionality.
However, their controlled synthesis with well-defined size, structure,
and properties remains a significant challenge. Herein, we introduce
a novel approach that combines depletion attraction and thermal activation
to induce the in situ formation of spherical superclusters
(AuSCs) from Au(I)-thiolate complexes within the assembly. Extensive
characterization and electron tomographic reconstruction reveal that
Au(I)-thiolate complexes can be sequentially transitioned into metallic
Au0, resulting in hollow nanoshell-like structures with
consistent size (∼110 nm) and diverse shell configurations.
Our results demonstrate that AuSCs with thinner shells, containing
a high concentration of Au(I)-thiolate complexes, exhibit the highest
PL, while AuSCs with thicker shells, containing high concentrations
of metallic gold atoms and low ligand density, show remarkable peroxidase-like
nanozyme activity in the 3,3′,5,5′-tetramethylbenzidine
(TMB) oxidation reaction.
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