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Cediranib is a small molecule inhibitor that has been used in various applications in the chemical industry.
One of the most common applications of Cediranib is as a metal-selective catalyst in a variety of chemical reactions, such as the hydroformylation of alkenes, the hydrogenation of aromatics, and the oxidation of alkanes.
In these reactions, Cediranib acts as a catalyst to facilitate the transformation of one chemical species into another, while simultaneously separating the metal catalyst from the reaction mixture.
Another application of Cediranib is in the field of photoelectrochemistry, where it is used as a sensitizer in dye-sensitized solar cells (DSSCs).
DSSCs are a type of solar cell that uses a photosensitizer dye absorbs light and converts it into electrical energy.
Cediranib is used as a sensitizer to enhance the efficiency of the DSSC by absorbing light in the visible range and transmitting it to the photosynthetic core of the cell.
Cediranib can also be used in the field of natural product synthesis.
In this application, Cediranib is used as a catalyst to facilitate the synthesis of complex organic molecules, such as terpenes and alkaloids, from simpler starting materials.
This is accomplished by activating the starting materials and coupling them together through a series of chemical reactions to produce the desired product.
In the field of materials science, Cediranib can be used as a precursor to synthesize metal-organic frameworks (MOFs).
MOFs are materials that consist of a three-dimensional network of metal ions and organic linkers.
They have a wide range of potential applications, such as in catalysis, gas storage, and separations.
By using Cediranib as a precursor, it is possible to synthesize MOFs with specific structures and properties tailored to specific applications.
In conclusion, Cediranib is a versatile molecule with a wide range of applications in the chemical industry.
Its use as a metal-selective catalyst, sensitizer, and precursor to synthesize other materials has made it an important tool in the field of chemical synthesis and catalysis.
As our understanding of Cediranib and its applications continues to grow, it is likely that new and exciting applications will be discovered, further expanding its utility in the chemical industry.
