4-N-HEXYLOXYBENZALDEHYDE CAS:5736-94-7

4-N-Hexyloxybenzaldehyde, with the molecular formula C₁₃H₁₈O₂, features a hexyl ether substituent on the para position of the benzaldehyde structure. This compound is synthesized through various methods, including the alkylation of p-hydroxybenzaldehyde or via nucleophilic substitution reactions involving hexanol and benzaldehyde derivatives. The hexyl group enhances the lipophilicity of the molecule, making it particularly useful in organic solvents and applications that require increased hydrophobicity. One of the primary applications of 4-N-hexyloxybenzaldehyde lies in organic synthesis, where it serves as a versatile intermediate. It can be utilized in the synthesis of complex organic molecules, including pharmaceuticals and agrochemicals. The aldehyde functional group allows for condensation reactions, enabling the formation of imines, enamines, or other carbonyl derivatives. These transformations are valuable in developing new therapeutic compounds or biologically active agents. In addition to its role in organic synthesis, 4-N-hexyloxybenzaldehyde has potential applications in materials chemistry. When incorporated into polymer matrices, it can influence material properties such as flexibility, thermal stability, and solubility. For instance, its use in synthesizing liquid crystalline polymers or coatings could lead to innovative materials with specific functionalities, such as improved optical properties or responsiveness to environmental stimuli. Furthermore, 4-N-hexyloxybenzaldehyde is also explored in fragrance chemistry due to its pleasant odor profile. Its aromatic nature makes it suitable for use in perfumes and scented products, contributing to the development of novel fragrances. Overall, 4-N-hexyloxybenzaldehyde is a significant compound in contemporary organic chemistry with diverse applications spanning pharmaceuticals, materials science, and fragrance development. Its structural characteristics and reactivity enable researchers and industrial chemists to explore innovative solutions and advancements in multiple fields. Understanding its properties will continue to promote its utilization in designing new chemical entities and functional materials, emphasizing its relevance in ongoing scientific exploration.