Understanding the intricate chemical structures of advanced organic intermediates is fundamental for scientists and engineers aiming to develop novel materials. Today, we explore 9-(4-chloro-6-phenyl-1,3,5-triazin-2-yl)-9H-carbazole, a compound designated by CAS number 1268244-56-9. This molecule is a fascinating example of how combining distinct functional units can lead to materials with desirable electronic and optical properties, particularly for applications in organic electronics like OLEDs.

At its core, the name itself reveals the key structural components. The molecule features a carbazole moiety, a bicyclic aromatic heterocycle known for its excellent hole-transporting capabilities and high thermal stability. Carbazole units are frequently incorporated into organic semiconductors to facilitate the movement of positive charges. Attached to the carbazole nitrogen is a substituted 1,3,5-triazine ring. Triazines are nitrogen-rich heterocycles that are often electron-deficient, making them excellent candidates for electron-transporting layers or as emissive cores in fluorescent and phosphorescent materials.

The specific substitution pattern on the triazine ring is also critical. In CAS 1268244-56-9, the triazine is linked to a phenyl group and a chlorine atom. The phenyl group contributes to extended conjugation and can influence intermolecular packing and solid-state properties. The chlorine atom, being an electronegative substituent, can further modulate the electronic properties of the triazine ring, affecting its electron affinity and potentially its emission wavelength. The overall molecular formula for this compound is C21H13ClN4, with a molecular weight of approximately 356.81 g/mol.

For researchers and procurement specialists looking to buy 9-(4-chloro-6-phenyl-1,3,5-triazin-2-yl)-9H-carbazole, understanding its structural nuances helps in predicting its behavior in synthesis and application. As a leading manufacturer of fine chemical intermediates, we ensure that our product meets high purity standards, typically exceeding 97%, to guarantee optimal performance in sensitive applications. Our role as a reliable supplier extends to providing accurate technical data that supports your material design and development efforts.

The strategic synthesis of such hybrid molecules allows for the creation of materials with fine-tuned energy levels, improved charge balance, and enhanced device efficiency. If your work requires this specific carbazole-triazine derivative, seeking a reputable manufacturer in China like us provides access to high-quality C21H13ClN4 at competitive prices. We are dedicated to supporting innovation in material science by providing the essential building blocks you need.