Rod-like In 2 O 3Àx (OH) y nanocrystal superstructure enhanced solar methanol synthesis with a remarkable production rate (0.06 mmol g cat À1 h À1 ) and selectivity (50%) at atmospheric pressure.
Chiral epoxides are important intermediates in chemistry and biology. The high-throughput screening of asymmetric epoxidation conditions requires fast determination of the absolute configurations and ee values of chiral epoxides. Herein, we report molecular recognition and chiroptical sensing of epoxides in water using endo-functionalized molecular tubes. The absolute configurations and ee values were simultaneously determined by circular dichroism spectroscopy. In addition, real-time monitoring as well as the application to real asymmetric epoxidation was demonstrated. The method is simple, environmentally friendly, and amenable to high-throughput screening.
Selective recognition of neutral hydrophilic molecules in water is a challenge for supramolecular chemistry but commonplace in nature. By mimicking the binding pocket of natural receptors, endo-functionalized molecular tubes are proposed to meet this challenge. We found that two molecular tubes with inwardly directed hydrogen-bond donors recognize highly hydrophilic solvent molecules in water with high selectivity. In the complexes, hydrogen bonding occurs in the deep and hydrophobic cavity. The cooperative action between hydrogen bonding and hydrophobic effects accounts for the high affinity and selectivity. The molecular receptor is fluorescent and can detect concentrations of 1,4-dioxane-a known carcinogen and persistent environmental contaminant-in water at a limit of 119 ppb. The method simplifies the analytic procedure for this highly hydrophilic molecule.
The conversion of CO2 into
fuels and feedstock chemicals via photothermal catalysis
holds promise for efficient solar
energy utilization to tackle the global energy shortage and climate
change. Despite recent advances, it is of emerging interest to explore
promising materials with excellent photothermal properties to boost
the performance of photothermal CO2 catalysis. Here, we
report the discovery of MXene materials as superior photothermal supports
for metal nanoparticles. As a proof-of-concept study, we demonstrate
that Nb2C and Ti3C2, two typical
MXene materials, can enhance the photothermal effect and thus boost
the photothermal catalytic activity of Ni nanoparticles. A record
CO2 conversion rate of 8.50 mol·gNi
–1·h–1 is achieved for Nb2C-nanosheet-supported Ni nanoparticles under intense illumination.
Our study bridges the gap between photothermal MXene materials and
photothermal CO2 catalysis toward more efficient solar-to-chemical
energy conversions and stimulates the interest in MXene-supported
metal nanoparticles for other heterogeneous catalytic reactions, particularly
driven by sunlight.
The efficiency of heterogeneous photocatalysis for converting solar to chemical energy is low on a per photon basis mainly because of the difficulty of capturing and utilizing light across the entire solar spectral wavelength range. This challenge is addressed herein with a plasmonic superstructure, fashioned as an array of nanoscale needles comprising cobalt nanocrystals assembled within a sheath of porous silica grown on a fluorine tin oxide substrate. This plasmonic superstructure can strongly absorb sunlight through different mechanisms including enhanced plasmonic excitation by the hybridization of Co nanoparticles in close proximity, as well as inter‐ and intra‐band transitions. With nearly 100% sunlight harvesting ability, it drives the photothermal hydrogenation of carbon dioxide with a 20‐fold rate increase from the silica‐supported cobalt catalyst. The present work bridges the gap between strong light‐absorbing plasmonic superstructures with photothermal CO2 catalysis toward the complete utilization of the solar energy.
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