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Synthetic routes of Flubanilate: An Overview in the Chemical Industry
Flubanilate is an important chemical compound that is widely used in the chemical industry.
It is a versatile chemical that has a wide range of applications in various fields, including the production of pharmaceuticals, agrochemicals, and dyes.
The chemical structure of Flubanilate is complex, and it is synthesized through several different routes.
In this article, we will discuss the different synthetic routes of Flubanilate, their advantages, and disadvantages.
- The Basic Synthesis Route
The basic synthesis route of Flubanilate involves the reaction of aniline with para-nitrophenol in the presence of an acid catalyst.
This reaction results in the formation of Flubanilic acid, which is then converted into Flubanilate through a series of chemical reactions.
This route is widely used in the chemical industry, as it is relatively simple and inexpensive.
Advantages of the Basic Synthesis Route:
- The basic synthesis route is relatively simple and inexpensive, making it a popular choice in the chemical industry.
- The reaction involves readily available starting materials, making it easy to produce Flubanilate in large quantities.
Disadvantages of the Basic Synthesis Route:
- The basic synthesis route produces a crude form of Flubanilate that requires further purification, which can be time-consuming and costly.
- The reaction produces a large amount of waste material, which can be environmentally hazardous if not disposed of properly.
- The Direct Synthesis Route
The direct synthesis route of Flubanilate involves the reaction of aniline with para-nitrophenol and sodium hydroxide in the presence of a solvent.
This reaction results in the formation of Flubanilate, which can then be purified and used in various applications.
This route is more complex than the basic synthesis route, but it produces a higher quality product with a higher yield.
Advantages of the Direct Synthesis Route:
- The direct synthesis route produces a higher quality product with a higher yield, making it a more efficient choice in the chemical industry.
- The reaction involves fewer steps,
