Atomically precise metal nanoclusters (NCs) have garnered
significant
interest due to their unique atomic stacking structures, the effect
of quantum confinement, and enriched active sites but suffer from
thermal- or light-induced poor instability and self-aggregation, together
with in situ self-conversion to conventional metal nanoparticles (NPs).
How to effectively harness the generic detrimental self-transformation
property of metal NCs has so far not garnered immense attention within
the realm of catalysis. In this work, we develop a layer-by-layer
assembly technology to accurately anchor metal NCs to the metal oxide
matrix. Then, the anchoring of metal NCs to metal NPs is triggered
by a simple thermal treatment that enables precise control over the
interface structure, resulting in a hollow core–shell heterostructure
with a metal core (Au, Ag) encapsulated by a metal oxide (CeO2, Fe2O3, SnO2) shell. Benefiting
from the synergistic interplay between metal NPs and the metal oxide
substrate, such self-assembled metal NPs@metal oxide heterostructures
display excellent catalytic activities and stability in the reduction
of aromatic nitro compounds. The detailed catalytic mechanism is elucidated.
Our work offers fresh impetus for the judicious utilization of the
inherent instability of metal NCs for catalytic selective organic
transformation.