Organic chemistry, at its core, is the art of building complex molecules from simpler ones. The availability of versatile building blocks is fundamental to this process, enabling chemists to design and synthesize compounds with specific properties and functions. Tetra-(4-pyridylphenyl)ethylene, identified by CAS number 1227195-24-5, stands out as such a compound, offering a unique combination of structural features that make it valuable in various branches of organic synthesis and material science.

Understanding the Molecular Architecture

Tetra-(4-pyridylphenyl)ethylene is characterized by a central ethene (double bond) core substituted with four phenyl rings. Each phenyl ring, in turn, is attached to a pyridine ring at its para position. This arrangement results in a molecule with a high degree of conjugation and the presence of multiple nitrogen atoms within the pyridine heterocycles. Typically supplied as an off-white powder with a minimum purity of 97%, its molecular formula is C46H32N4 and its molecular weight is 640.77 g/mol. This substantial and well-defined structure is key to its utility.

Key Features and Reactivity

The versatility of Tetra-(4-pyridylphenyl)ethylene arises from several key features:

  • Conjugated System: The extensive pi-electron system, spanning from the pyridine rings through the phenyl rings to the ethene core, imparts unique electronic and optical properties. This conjugation is crucial for applications in organic electronics, such as OLEDs and organic photovoltaics, where charge transport and light absorption/emission are primary functions.
  • Nitrogen Heterocycles (Pyridine): The presence of pyridine rings introduces nitrogen atoms into the molecule. These nitrogen atoms can act as Lewis bases, capable of coordinating with metal ions. This property makes the compound a potential ligand in coordination chemistry and catalysis. It also influences the electronic distribution within the molecule, affecting its reactivity and charge transport characteristics.
  • Phenyl Linkers: The phenyl groups provide rigidity to the molecular structure and facilitate the electronic communication between the ethene core and the pyridine rings. They also offer sites for potential functionalization, allowing chemists to further modify the molecule's properties.

Applications Across Disciplines

The multifaceted nature of Tetra-(4-pyridylphenyl)ethylene allows it to be employed in a range of scientific and industrial fields:

  • Materials Science and Organic Electronics: As discussed previously, its electronic and photophysical properties make it a prime candidate for use in OLEDs, contributing to charge transport and emission layers. It can also be utilized in the development of organic semiconductors, sensors, and other optoelectronic devices.
  • Pharmaceutical Intermediates: In medicinal chemistry, it serves as a valuable scaffold or precursor for synthesizing complex drug molecules. The nitrogen atoms and aromatic rings provide points for chemical modification and interaction with biological targets.
  • Catalysis and Coordination Chemistry: The pyridine nitrogen atoms can coordinate with transition metals, forming complexes that may exhibit catalytic activity. This opens avenues for its use in various catalytic transformations in organic synthesis.
  • Supramolecular Chemistry: The well-defined structure and potential for intermolecular interactions (e.g., pi-pi stacking) make it an interesting component for building self-assembled structures and supramolecular architectures.

Strategic Sourcing from Manufacturers

For researchers and industry professionals looking to buy Tetra-(4-pyridylphenyl)ethylene, identifying reliable suppliers is crucial. China-based chemical manufacturers are often at the forefront of producing such specialty organic compounds. When searching, keywords like 'organic chemistry building blocks,' 'buy CAS 1227195-24-5,' or 'specialty chemical supplier China' are effective. Buyers should always prioritize suppliers who can guarantee high purity, consistent quality, and scalable production capacities, offering competitive prices and samples for evaluation.

Conclusion

Tetra-(4-pyridylphenyl)ethylene (CAS 1227195-24-5) is a testament to the power of molecular design in organic chemistry. Its unique structure and resulting properties make it a highly versatile compound with applications spanning cutting-edge electronics to pharmaceutical development and beyond. By partnering with experienced manufacturers, scientists and engineers can leverage this exceptional building block to drive innovation and create the advanced materials of tomorrow. We are committed to being a leading supplier, providing the high-purity materials that power scientific and industrial advancement.