Perfluorohexyl Ethylene, identified by its CAS number 25291-17-2, is a fascinating chemical compound that finds significant utility as a fluorinated organic intermediate. Its molecular formula, C8H3F13, reveals a structure where a linear perfluorohexyl chain (a chain of eight carbon atoms, with all hydrogen atoms replaced by fluorine atoms) is attached to an ethylene group (C2H4), specifically a vinyl group (-CH=CH2). This unique structure bestows upon it a distinct set of chemical and physical properties that are highly sought after in specialized applications.

The presence of a substantial number of fluorine atoms (13 in this case) significantly influences the molecule's characteristics. Fluorine is highly electronegative, leading to strong carbon-fluorine bonds. This results in high thermal stability, chemical inertness, and low surface energy. These attributes are precisely why compounds like Perfluorohexyl Ethylene are valuable. The ethylene group, on the other hand, provides a site for reactivity, allowing the molecule to participate in polymerization and various addition reactions, making it a versatile building block for organic synthesis.

As a supplier of this critical intermediate, understanding its behavior is key. Perfluorohexyl Ethylene exists as a clear, colorless liquid at room temperature, with a boiling point around 102-104°C and a density of 1.52 g/mL. Its limited solubility in water but slight solubility in common organic solvents like methanol and chloroform is a direct consequence of its highly fluorinated nature. When researchers look to buy Perfluorohexyl Ethylene, they are often seeking to harness its capacity to create materials that resist heat, chemicals, and adhesion.

The importance of sourcing high-quality Perfluorohexyl Ethylene (CAS 25291-17-2) cannot be overstated for precise chemical syntheses. Whether used as a monomer for specialty polymers or as a functional group in complex organic molecules, its purity and consistent supply are vital. Manufacturers and suppliers play a crucial role in making this advanced chemical accessible for research and industrial purposes, underpinning advancements in materials science and chemical engineering.