News Release

Scientists design bifunctional catalyst to solve environmental pollution problems

Uses 3D POV-based metal-organic framework

Peer-Reviewed Publication

Tsinghua University Press

Bifunctional Catalyst to Solve Environmental Pollution

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Researchers have developed a new three-dimensional 2-fold interpenetrating polyoxovanadate-based metal-organic framework that shows satisfying catalytic performances for the selective oxidation of 2-chloroethyl ethyl sulfide (CEES) to corresponding sulfoxide (CEESO) and photodegradation toward phenol, 2-chlorophenol and m-cresol under visible light.

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Credit: Polyoxometalates, Tsinghua University Press

A team of researchers from Bohai University in China have designed and synthesized a bifunctional catalyst that can solve the environmental pollution caused by mustard gas and phenolic compounds. They synthesized this bifunctional catalyst, a new three-dimensional polyoxovanadate-based metal-organic framework, under hydrothermal conditions.

 

Their work is published in the journal Polyoxometalates on March 4, 2024.

 

The team’s bifunctional catalyst shows satisfying catalytic performances for the selective oxidation of 2-chloroethyl ethyl sulfide (CEES) to corresponding sulfoxide (CEESO) and photodegradation toward phenol, CEES, and m-cresol under visible light. A bifunctional catalyst is one that provides both acidic and basic catalytic functions.

 

In recent years, the problem of organic hazardous substances that cause pollution has raised considerable concern. Scientists have focused their work on developing reasonable methods for degrading these organic hazardous substances. CEES, or mustard gas, is a chemical warfare agent that causes severe skin diseases, strong irritation of the respiratory tract, and even death. Since mustard gas was first used in World War I, researchers have sought ways to detoxify this chemical warfare agent. M-cresol is an organic compound that is extracted from coal tar and is used in the production of other chemicals, including pesticides. It is corrosive to the eyes, skin, and respiratory tract.

 

Phenolic pollutants often persist in polluted waste water that flows from industrial, agricultural, and domestic work. Once they make their way into the water systems, phenolic pollutants can be very harmful to humans and the environment. These pollutants can be acutely toxic to the point of causing the death of animals, birds, or fish. They can also stunt the growth of or kill plants. Scientists have been working to design by synthesis new bifunctional catalysts that can convert these types of dangerous pollutants into low toxicity degradants. However, up to this point in time, scientists had not successfully achieved the preparation of high dimensional interpenetrating metal-organic frameworks that can act as bifunctional catalysts capable of oxidizing CEES to CEESO and degrading phenolic compounds under visible light.

 

Polyoxometalates (POMs) are a kind of inorganic metal oxide clusters with diverse architectural structures and attractive properties. Because of their wide array of structures and functionalities, they are one of the most useful classes of inorganic molecular materials. Within the POMs family, polyoxovanadates (POVs) have attracted increasing attention from scientists because of their diverse structures and remarkable properties.

 

The researchers used a bis-pyridyl-bis-amide ligand to construct the new POV-based metal-organic framework. They then studied the 3D POV-based metal-organic framework using single crystal X-ray diffraction analysis, IR spectroscopy, and powder X-ray diffraction. “The long feature of the amide-based ligand induces the formation of the unusual 2-fold interpenetrating structure,” said Guo-Cheng Liu, an associate professor at Bohai University.

 

The team’s bifunctional catalyst successfully catalyzed the selective oxidation of toxic CEES to the corresponding safer sulfoxide in the presence of H2O2, or hydrogen peroxide, as an eco-friendly oxidant. It worked under visible light with an effective recyclability and stability. The successful conversion was greater than 99 percent and the selectivity was 97 percent.

 

In addition, the bifunctional catalyst showed excellent photocatalytic degradation activity toward phenol, CEES, and m-cresol under visible light. The team successfully achieved degradation efficiencies above 92.6 percent for 140 minutes. They also investigated in detail the photocatalytic reaction kinetics, the mechanisms of photodegradation, and recycling capability of phenol. “This work provides important guidance for the development of new POVs-based bifunctional catalysts for the decontamination in water,” said Liu.

 

The research team includes Shuang Li, Yuan Zheng, Guo-Cheng Liu, Xiao-Hui Li, Zhong Zhang, and Xiu-Li Wang from the Liaoning Professional Technology Innovation Center of Liaoning Province for Conversion Materials of Solar Cell, College of Chemistry and Materials Engineering, Bohai University, China.

 

The research is funded by the National Natural Science Foundation of China and the Natural Science Foundation and Education Department of Liaoning Province.

 


About Polyoxometalates  

Polyoxometalates is a peer-reviewed, international and interdisciplinary research journal that focuses on all aspects of polyoxometalates, featured in rapid review and fast publishing, sponsored by Tsinghua University and published by Tsinghua University Press. Submissions are solicited in all topical areas, ranging from basic aspects of the science of polyoxometalates to practical applications of such materials. Polyoxometalates offers readers an attractive mix of authoritative and comprehensive Reviews, original cutting-edge research in Communication and Full Paper formats, Comments, and Highlight.

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