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Synthetic routes of 3-(BROMOMETHYL)PYRIDAZINE: A Comprehensive Overview
3-(BROMOMETHYL)PYRIDAZINE is an important organic compound with diverse applications in the chemical industry.
Its synthesis has been studied extensively in the scientific literature, and several synthetic routes have been developed over the years.
In this article, we will provide a comprehensive overview of the different synthetic routes of 3-(BROMOMETHYL)PYRIDAZINE.
Route 1: via Pyrrole
One of the most common synthetic routes to 3-(BROMOMETHYL)PYRIDAZINE involves the conversion of pyrrole to 3-bromo-pyrridine using a halogenation reaction.
This is followed by the condensation of the resulting 3-bromo-pyrridine with methylamine to form 3-(BROMOMETHYL)PYRIDAZINE.
This route is relatively simple and offers a good yield of the desired product.
Route 2: via N-Bromosuccinimide
Another synthetic route to 3-(BROMOMETHYL)PYRIDAZINE involves the use of N-bromosuccinimide (NBS) as a reagent.
This reagent is a strong brominating agent that can readily brominate a variety of substrates.
The bromination of pyridine or its derivatives with NBS followed by reduction of the resulting N-bromamine with lithium aluminum hydride (LiAlH4) provides 3-(BROMOMETHYL)PYRIDAZINE.
This route is more complicated than the first route but provides a good yield of the desired product.
Route 3: via Chlorination
A third synthetic route to 3-(BROMOMETHYL)PYRIDAZINE involves the use of chlorination agents, such as thionyl chloride or oxalyl chloride, to convert the parent molecule to a halogenated derivative.
This halogenated derivative is then converted to 3-(BROMOMETHYL)PYRIDAZINE via a series of chemical reactions, including reduction and halogenation.
This route is more complicated than the first two routes and requires a higher level of chemical expertise.
Route 4: via Electrophilic Halogenation
A fourth synthetic route to 3-(BROMOMETHYL)PYRIDAZINE involves the use of electrophilic halogenation agents, such as N-bromosuccinimide or N-chlorosuccinimide, to provide the desired bromination or chlorination of the parent molecule.
This route is similar to route 2 but uses a different reagent.
This route is more complicated than the first two routes but provides a good yield of the desired product.
Overall, the synthetic routes to 3-(BROMOMETHYL)PYRIDAZINE are diverse and can vary in terms of complexity, yield, and cost.
The choice of route depends on the availability of reagents, the desired yield, and the required purity of the product.
However, regardless of the route chosen, 3-(BROMOMETHYL)PYRIDAZINE remains an important compound in the chemical industry with a wide range of applications.
