posted on 2023-12-28, 00:43authored byZhong Li, Yunwei Huang, Haoyang Li, Fenghua Zhang, Yazhou Ren, Wenxiong Shi, Qingda Liu, Xun Wang
Spatially confining isolated atomic sites in low-dimensional
nanostructures
is a promising strategy for preparing high-performance single-atom
catalysts (SACs). Herein, fascinating polyoxometalate cluster-based
single-walled nanotubes (POM-SWNTs) with atomically precise structures,
uniform diameter, and single-cluster wall thickness are constructed
by lacunary POM clusters (PW11 and P2W17 clusters). Isolated metal centers are accurately incorporated into
the PW11-SWNTs and P2W17-SWNTs supports.
The structures of the resulting MPW11-SWNTs and MP2W17-SWNTs are well established (M = Cu, Pt). Molecular
dynamics simulations demonstrate the stability of POM-SWNTs. Furthermore,
the turnover frequency of PtP2W17-SWNTs is 20
times higher than that of PtP2W17 cluster units
and 140 times higher than that of Pt nanoparticles in the alcoholysis
of dimethylphenylsilane. Theoretical studies indicate that incorporating
a Pt atom into the P2W17 support induces straightforward
electron transfer between them, combining the nanoconfined environment
to enhance the catalytic activity of PtP2W17-SWNTs. This work shows the feasibility of using subnanometric POM
clusters to assemble single-walled cluster nanotubes, highlighting
their potential to prepare superior SACs with precise structures.