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Synthetic routes of [99010-09-0], C13H17N3, are an important aspect of the chemical industry.
These routes involve the synthesis of a specific chemical compound, [99010-09-0], through various chemical reactions.
In this article, we will discuss the synthetic routes of [99010-09-0], C13H17N3, and how they are used in the chemical industry.
One of the most common synthetic routes for [99010-09-0] involves the use of a reaction called the Williamson ether synthesis.
In this reaction, an alcohol and an aromatic halide are reacted in the presence of a base to form an ether.
The [99010-09-0] molecule is then synthesized by treating the ether with a sulfuric acid catalyst.
This route is widely used in the chemical industry due to its simplicity and ease of use.
Another synthetic route for [99010-09-0] involves the use of a reaction called the Suzuki-Miyaura reaction.
This reaction involves the use of a palladium catalyst to couple an aryl boronic acid with a halogen-substituted alkene.
The resulting compound is then treated with a base to form the [99010-09-0] molecule.
This route is commonly used in organic synthesis due to the high efficiency of the Pd(0) catalyst.
A third synthetic route for [99010-09-0] involves the use of a reaction called the Stille reaction.
In this reaction, an aryl halide and a vinyl halide are reacted in the presence of a palladium catalyst to form a biaryl compound.
The [99010-09-0] molecule is then synthesized by treating the biaryl compound with a strong base.
This route is commonly used in organic synthesis due to its high yield and the simplicity of the reaction.
In conclusion, synthetic routes of [99010-09-0], C13H17N3, are an important aspect of the chemical industry.
These routes involve the synthesis of a specific chemical compound, [99010-09-0], through various chemical reactions.
The Williamson ether synthesis, the Suzuki-Miyaura reaction, and the Stille reaction are three common synthetic routes used in the chemical industry.
These routes are widely used due to their simplicity and efficiency in forming the [99010-09-0] molecule.
