Organic Electrosynthesis

As a green synthesis method that combines electrochemistry and organic chemistry, organic electrosynthesis has high selectivity, mild reaction conditions and low environmental impact. With the continuous development of technology, especially in the research of electrocatalytic materials and reaction mechanisms, organic electrosynthesis has a very broad application prospect in the fields of drug synthesis, materials science and green chemistry.

Redox mediator

Redox mediators play a key role in electrocatalytic reactions. They significantly improve catalytic efficiency and reaction rates by promoting efficient electron transfer. Whether used for energy storage and conversion (such as fuel cells, water splitting, battery technology) or for environmental governance (such as CO2 reduction), redox mediators provide important support for electrocatalytic reactions. In future energy and environmental technologies, the development of efficient and stable redox mediators remains one of the research hotspots.

N-O radical

Electrolytes

Electrolytes play a key role in electrochemical systems, supporting the conductivity of ions and ensuring current conduction, as well as regulating the performance and stability of batteries and other electrochemical devices. The selection and design of electrolytes have a profound impact on the efficiency, cycle life, safety and cost of electrochemical devices. With the emergence of new materials, the research and development of electrolytes has been continuously advanced, driving the development of modern batteries, fuel cells and supercapacitors.

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Organic Electrosynthesis

Redox mediator

N-O radical

Electrolytes

Quaternary ammonium salt

Pyridine salt

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