2 research outputs found
Hybridization of Metal Nanoparticles with Metal–Organic Frameworks Using Protein as Amphiphilic Stabilizer
Here,
a facile strategy is reported to efficiently hybridize metal nanoparticles
(MNPs) with typical metal–organic frameworks (MOFs) of ZIF-8
(zeolitic imidazolate framework-8), which employs bovine serum albumin
(BSA, a serum albumin protein derived from cows) as the amphiphilic
stabilizer to increase the affinity of MNP toward MOFs. For instance,
the as-synthesized PdNPs/ZIF-8 composites with diameter from 100 to
200 nm always maintain well-defined crystalline structure, and the
PdNPs with small size of ∼2 nm are well-dispersed in the crystal
of MOFs without serious aggregations due to the BSA stabilizer. In
Suzuki cross-coupling reactions of aryl halide, the PdNPs/ZIF-8 as
catalysts have exhibited high activity and satisfied reusability owing
to the use of BSA stabilizer as well as the fixing of MOFs matrixes.
In addition, the strategy also can be extended to synthesize other
kinds of MNPs/MOFs hybrid composites with tunable particle size, which
brings more opportunity for functional MOFs hybrid materials
Fabrication of Flexible Transparent Electrode with Enhanced Conductivity from Hierarchical Metal Grids
Flexible
transparent conductive electrodes (FTCEs) are essential
components for numerous optoelectronic devices. In this work, we have
fabricated the hierarchical metal grids (HMG) FTCEs by a facile and
low-cost, near-field photolithography strategy. Compared to normal
metal grids (MG), the HMG structure can provide distinctly increased
conductivity of the electrode yet without obvious reduction of the
optical transmittance. This HMG sample possesses excellent optoelectronic
performance and high mechanical flexibility, making it a promising
component for practical applications