Valeronitrile, with CAS number 110-59-8, stands out as a highly versatile compound in the realm of organic synthesis. Also known by names such as pentanenitrile and butyl cyanide, this colorless liquid serves as a fundamental building block, enabling chemists to construct more complex molecules. Its utility spans across various industries, including pharmaceuticals, agrochemicals, and materials science, making it a staple intermediate for many synthesis laboratories and manufacturing facilities.

The core of Valeronitrile's synthetic utility lies in its nitrile functional group (-C≡N). This group is known for its electrophilic carbon atom and nucleophilic nitrogen atom, allowing it to participate in a wide array of chemical transformations. For instance, hydrolysis of the nitrile yields pentanoic acid, while reduction can produce pentylamine. These reactions are foundational for introducing specific functionalities into target organic molecules. Furthermore, the nitrile group can engage in cycloaddition reactions, Grignard reactions, and alkylation processes, offering chemists numerous pathways to explore.

For chemists and R&D scientists, sourcing high-quality Valeronitrile is crucial for ensuring successful and reproducible synthetic outcomes. Many chemical suppliers, particularly those based in China, offer Valeronitrile with guaranteed purity levels, typically exceeding 98% by GC. When you buy Valeronitrile, understanding its reactivity profile and ensuring it meets your specific purity requirements will streamline your research and development efforts.

The economic advantage of sourcing Valeronitrile from established manufacturers and suppliers in China is significant. Competitive pricing, coupled with the availability of various quantities, makes it an accessible intermediate for both academic research and industrial-scale production. When planning your synthesis, remember to consider suppliers who can provide detailed technical support and reliable delivery schedules.

In conclusion, Valeronitrile (CAS 110-59-8) offers chemists a powerful tool for molecular construction. Its predictable reactivity and broad applicability make it an invaluable intermediate. By understanding its synthesis applications and sourcing it strategically, researchers and manufacturers can effectively leverage this chemical building block for innovation.