For the first time we report syntheses of a family of functional polyphenylenepyridyl dendrons with different generations and structures such as focal groups, periphery, and a combination of phenylene and pyridyl moieties in the dendron interior using a Diels−Alder approach and a divergent method. The dendron structure and composition were confirmed using NMR spectroscopy, MALDI-TOF mass spectrometry, FTIR, and elemental analysis. As a proof of concept that these dendrons can be successfully used for the development of nanocomposites, synthesis of iron oxide nanoparticles was carried out in the presence of thermally stable dendrons as capping molecules followed by formation of Pd NPs in the dendron shells. This resulted in magnetically recoverable catalysts exhibiting exceptional performance in selective hydrogenation of dimethylethynylcarbinol (DMEC) to dimethylvinylcarbinol (DMVC).
This minireview discusses controlled chemical synthetic advancements of nickel nitride and its composites, their fundamental properties, and energy-related applications.
Here we report the functionalization of monodisperse iron oxide nanoparticles (NPs) with commercially available functional acids containing multiple double bonds such as linolenic (LLA) and linoleic (LEA) acids or pyridine moieties such as 6-methylpyridine-2-carboxylic acid, isonicotinic acid, 3-hydroxypicolinic acid, and 6-(1-piperidinyl)pyridine-3-carboxlic acid (PPCA). Both double bonds and pyridine groups can be reacted with noble metal compounds to form catalytically active species in the exterior of magnetic NPs, thus making them promising magnetically recoverable catalysts. We determined that both LLA and LEA stabilize magnetic iron oxide NPs, allowing the formation of π-complexes with bis(acetonitrile)dichloropalladium(II) in the NP shells. In both cases, this leads to the formation of NP aggregates because of interparticle complexation. In the case of pyridine-containing ligands, only PPCA with two N-containing rings is able to provide NP stabilization and functionalization whereas other pyridine-containing acids did now allow sufficient steric stabilization. The interaction of PPCA-based particles with Pd acetate also leads to aggregation because of interparticle interactions, but the aggregates that are formed are much smaller. Nevertheless, the catalytic properties in the selective hydrogenation of dimethylethynylcarbinol (DMEC) to dimethylvinylcarbinol were the best for the catalyst based on LLA, demonstrating that the NP aggregates in all cases are penetrable for DMEC. Easy magnetic separation of this catalyst from the reaction solution makes it promising as a magnetically recoverable catalyst.
Nanostructured noble-metal catalysts
traditionally suffer from
sintering under high operating temperatures, leading to durability
issues and process limitations. The encapsulation of nanostructured
catalysts to prevent loss of activity through thermal sintering, while
maintaining accessibility of active sites, remains a great challenge
in the catalysis community. Here, we report a robust and regenerable
palladium-based catalyst, wherein palladium particles are intercalated
into the three-dimensional framework of SBA-15-type mesoporous silica.
The encapsulated Pd active sites remain catalytically active as demonstrated
in high-temperature/pressure phenol hydrodeoxygenation reactions.
The confinement of Pd particles in the walls of SBA-15 prevents particle
sintering at high temperatures. Moreover, a partially deactivated
catalyst containing intercalated particles is regenerated almost completely
even after several reaction cycles. In contrast, Pd particles, which
are not encapsulated within the SBA-15 framework, sinter and do not
recover prior activity after a regeneration procedure.
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