10-(1,1':3',1''-Terphenyl-5'-yl)anthracene-9-boronic Acid, identified by its CAS number 1415334-59-6, stands as a pivotal chemical compound in the realm of advanced materials. With a molecular formula of C32H23BO2 and a molecular weight of 450.34 g/mol, this complex organic molecule is gaining increasing attention from researchers and industries alike for its unique properties and versatile applications. Its intricate structure, combining anthracene and terphenyl moieties with a boronic acid group, grants it distinct characteristics essential for high-performance applications.

Physically, this compound is presented as a yellow crystalline powder, a common appearance for many organic intermediates. A crucial aspect for its utility in sophisticated applications is its purity. Reputable sources consistently offer this product with a high assay, typically ≥97.0% purity as determined by High-Performance Liquid Chromatography (HPLC). Such stringent purity standards are imperative to ensure optimal performance and reliable results in sensitive electronic applications. Proper storage is also vital to maintain its integrity; it should be kept in a cool, well-ventilated place, away from direct sunlight and moisture, to preserve its stability and reactivity over time.

The primary and most significant application of 10-(1,1':3',1''-Terphenyl-5'-yl)anthracene-9-boronic Acid lies within the field of Organic Light-Emitting Diodes (OLEDs). It serves as a key intermediate in the synthesis of novel OLED materials. Boronic acids are exceptionally versatile building blocks in organic chemistry, particularly celebrated for their participation in cross-coupling reactions such as the Suzuki-Miyaura coupling. These reactions are instrumental in constructing the complex molecular frameworks required for efficient and stable OLED emitters and host materials. By facilitating the creation of molecules with tailored electronic and photophysical properties, this boronic acid derivative contributes directly to enhancing the brightness, efficiency, and color purity of OLED displays, which are increasingly prevalent in modern televisions, smartphones, and lighting solutions.

Beyond its direct role in OLEDs, the compound also finds utility as a fundamental small molecule semiconductor building block. Its anthracene core is well-known for its excellent charge transport properties, while the terphenyl substituents contribute to molecular rigidity and solubility, both critical factors in developing high-performance organic semiconductor devices. This makes it an invaluable precursor for synthesizing materials used in other organic electronic applications, including organic field-effect transistors (OFETs), organic photovoltaics (OPVs), and sensors. The ability to precisely control the molecular architecture through the judicious use of such intermediates paves the way for innovations in flexible electronics, energy conversion, and advanced sensing technologies.

The demand for high-quality 10-(1,1':3',1''-Terphenyl-5'-yl)anthracene-9-boronic Acid is steadily rising as organic electronics continue their rapid development. For researchers and industrial clients seeking to advance their projects, identifying a reliable manufacturer and supplier is critical. When you aim to buy or purchase this specialized boronic acid, it is essential to consider the supplier's commitment to quality control, consistent product availability, and comprehensive technical support. The price of this advanced chemical intermediate can vary based on purity, quantity, and supply chain efficiency, emphasizing the importance of working with an established provider capable of meeting diverse requirements efficiently and cost-effectively.

In conclusion, 10-(1,1':3',1''-Terphenyl-5'-yl)anthracene-9-boronic Acid represents a crucial component in the toolkit of organic chemists developing next-generation electronic materials. Its indispensable role as an OLED intermediate and a versatile semiconductor building block underscores its importance in shaping the future of display technology and organic electronics. As innovation in these fields accelerates, the demand for meticulously produced and rigorously tested chemical intermediates like this boronic acid will only grow, reinforcing its status as a cornerstone of advanced material science.