In the intricate world of specialty chemical synthesis, certain molecules serve as fundamental building blocks, enabling the creation of advanced materials and complex compounds. 6-Undecanol (CAS 23708-56-7), a C11 fatty alcohol, has carved out a significant niche due to its versatile reactivity and the unique properties it imparts to downstream products. This article explores the role of 6-Undecanol as a key intermediate for manufacturers and R&D scientists, highlighting its importance in various synthetic pathways.

Understanding 6-Undecanol: The Chemical Backbone

Chemically known as undecan-6-ol, this secondary alcohol boasts a molecular formula of C11H24O and a molecular weight of approximately 172.31 g/mol. Its structure features a moderately long hydrocarbon chain with a single hydroxyl (-OH) group positioned centrally. This structural characteristic makes it amenable to a range of chemical transformations. Typically supplied with high purity (e.g., 97% or more), 6-Undecanol's physical properties, such as its melting point (25-26°C) and boiling point (229.7°C), are critical considerations for process design.

6-Undecanol in Synthesis: Diverse Applications

The reactivity of the hydroxyl group in 6-Undecanol allows it to participate in numerous organic reactions, making it a valuable intermediate for specialty chemical manufacturers. Here are some key synthetic applications:

  • Esterification Reactions: 6-Undecanol readily reacts with carboxylic acids or acid derivatives to form esters. These undecyl esters can possess unique properties, finding use as emollients in cosmetics, plasticizers, lubricants, or as intermediates for further synthesis. For businesses looking to buy 6-undecanol for ester production, sourcing from a reliable manufacturer is essential.
  • Oxidation to Ketones: Oxidation of the secondary alcohol functionality yields 6-undecanone. This ketone is itself a valuable intermediate, employed in the synthesis of fragrances, pharmaceuticals, and agrochemicals. Suppliers of 6-undecanol are often able to provide related ketones or the precursor itself.
  • Ether Formation: Through Williamson ether synthesis or other etherification methods, 6-Undecanol can be converted into undecyl ethers. These compounds might exhibit surface-active properties or be used as specialty solvents.
  • Halogenation and Nucleophilic Substitution: The hydroxyl group can be replaced by halogens, creating haloalkanes that are reactive intermediates for carbon-carbon bond formation or other nucleophilic substitution reactions. This opens doors to a wide array of complex organic molecules.
  • Derivatization for Advanced Materials: In materials science, 6-Undecanol can be derivatized to introduce specific functionalities onto surfaces or into polymer backbones, modifying properties like hydrophobicity, flexibility, or compatibility.

Procurement Considerations for R&D and Manufacturing

For scientists and manufacturers, sourcing 6-Undecanol (CAS 23708-56-7) requires attention to detail. When seeking a supplier, inquire about:

  • Quality and Purity: Confirm that the purity meets your specific application needs.
  • Scalability: Can the supplier provide quantities ranging from grams for R&D to metric tons for commercial production?
  • Technical Support: Does the manufacturer or distributor offer technical assistance regarding product applications or synthesis?
  • Pricing and Lead Times: Obtain quotes and discuss lead times to ensure integration into your production schedule.

In conclusion, 6-Undecanol is a vital intermediate that empowers specialty chemical synthesis. Its versatile reactivity and specific properties make it indispensable for creating value-added products. By partnering with reputable manufacturers and understanding its synthetic potential, businesses can effectively leverage this compound to drive innovation and meet market demands.