The relentless pursuit of advanced materials with enhanced properties is a driving force in modern industry. Chemical intermediates play a pivotal role in this innovation, acting as the foundational building blocks for novel polymers, resins, and specialty chemicals. (4-Vinylphenyl)methanol, with its CAS number 1074-61-9, is a prime example of such a critical intermediate, offering unique structural features that enable the development of cutting-edge materials. For professionals in material science and chemical engineering, understanding its properties and sourcing it from reliable providers is paramount.

Understanding (4-Vinylphenyl)methanol's Unique Properties

(4-Vinylphenyl)methanol, also known as 4-Vinylbenzyl alcohol, is a bifunctional organic compound. Its chemical structure features a phenyl ring adorned with a vinyl group (-CH=CH2) and a hydroxymethyl group (-CH2OH). This duality is the source of its significant utility:

  • Vinyl Group Reactivity: The vinyl moiety is highly reactive and readily participates in free-radical polymerization, cationic polymerization, and other addition reactions. This makes (4-Vinylphenyl)methanol an excellent monomer for creating polymers and copolymers with tailored characteristics.
  • Hydroxymethyl Group Functionality: The alcohol group can be involved in a variety of chemical reactions, including esterification, etherification, oxidation, and condensation. This allows for further functionalization of polymers or its use in multi-step syntheses.
  • Physical Characteristics: Typically presented as a light yellow liquid, (4-Vinylphenyl)methanol is valued for its high purity, often specified at 99% or more. This purity is critical for achieving consistent results in material synthesis and ensuring the desired performance of the final products.

Applications in Advanced Material Development

The unique combination of reactive groups makes (4-Vinylphenyl)methanol a sought-after component in several areas of advanced material development:

  • Specialty Polymers and Resins: It is widely used as a monomer or co-monomer in the synthesis of specialty polymers. These can include resins with enhanced thermal stability, optical clarity, or specific adhesion properties, finding use in high-performance coatings, advanced adhesives, and composite materials.
  • Functional Coatings: The ability to introduce hydroxyl groups onto polymer backbones via (4-Vinylphenyl)methanol allows for the development of functional coatings that can be further modified, cross-linked, or exhibit improved surface properties like wettability or adhesion.
  • Electronics and Optoelectronics: In the electronics sector, monomers like (4-Vinylphenyl)methanol are explored for creating materials used in photolithography, encapsulants, or components for displays, where precise chemical structures and purity are essential for performance.
  • Crosslinking and Modification: Beyond acting as a primary monomer, it can be incorporated in smaller percentages to modify existing polymer chains or act as a crosslinking agent to improve the mechanical strength, solvent resistance, and thermal properties of materials.

Strategic Sourcing for Quality and Cost-Effectiveness

For material scientists and procurement professionals aiming to buy (4-Vinylphenyl)methanol, identifying a reputable manufacturer orsupplier is paramount. High-purity (99%+) material is critical for ensuring predictable outcomes in advanced material synthesis. When seeking to optimize costs, exploring options from leading chemical producers, particularly those based in China, can be highly beneficial. These suppliers often offer competitive (4-Vinylphenyl)methanol price points while maintaining stringent quality control standards.

It is essential to request comprehensive product documentation, including Certificates of Analysis, when inquiring about (4-Vinylphenyl)methanol CAS 1074-61-9. Companies like NINGBO INNO PHARMCHEM CO.,LTD. specialize in providing high-quality chemical intermediates, supporting your efforts in advanced material development with reliable products and efficient service. They are a valuable resource for securing the materials needed for cutting-edge research and manufacturing.

In conclusion, (4-Vinylphenyl)methanol is a vital organic intermediate that empowers the development of next-generation materials. By focusing on quality, understanding its chemical potential, and sourcing strategically from trusted providers, researchers and manufacturers can unlock new possibilities in material science and engineering.