The world of advanced electronics is constantly pushing boundaries, with OLED technology leading the charge in display innovation. The vibrant colors, deep blacks, and remarkable energy efficiency of OLED screens are the result of complex organic molecules meticulously synthesized. A crucial player in this field is 2-Bromodibenzofuran, identified by its CAS number 86-76-0. This organic compound serves as a vital intermediate, underpinning the development of high-performance materials essential for cutting-edge display devices. For R&D professionals and procurement managers, understanding the properties and sourcing of such chemicals is key.

Chemical Properties and Purity of 2-Bromodibenzofuran

2-Bromodibenzofuran, represented by the molecular formula C12H7BrO, is a derivative of dibenzofuran. Its common synonyms include 2-bromo-dibenzouran. Typically presented as a white powder, its high purity, often specified at 98.0% or greater, is a critical attribute for its use in electronic materials. The compound possesses a significant molecular weight of 247.09 g/mol and exhibits a high boiling point of 651.9ºC and a flash point of 348.1ºC. These characteristics highlight its stability, making it robust enough to withstand the often harsh conditions of organic synthesis processes required for OLED material production. This inherent stability ensures the integrity of the molecule throughout various reaction steps.

Applications in the OLED Material Synthesis Pathway

The primary contribution of 2-Bromodibenzofuran to OLED technology lies in its role as a precursor for synthesizing functional organic materials. The bromine atom at the second position of the dibenzofuran ring is highly reactive, serving as an ideal functional group for various coupling reactions. These reactions, such as palladium-catalyzed cross-couplings, are fundamental in building the extended conjugated systems that characterize OLED materials. These systems are crucial for the efficient transport of electrons and holes, as well as for the emission of light. By incorporating the dibenzofuran core, researchers can fine-tune the electronic and optical properties of the resultant materials, leading to improved device efficiency, color purity, and operational lifetime in OLED displays. Its utility extends to creating host materials, charge transport layers, and emissive dopants.

Strategic Sourcing of 2-Bromodibenzofuran from China

In the global supply chain for specialty chemicals, China has emerged as a dominant force. Manufacturers in China offer a wide array of high-purity organic intermediates, including 2-Bromodibenzofuran, to serve the burgeoning OLED industry. For companies seeking to buy 2-Bromodibenzofuran, partnering with a reputable Chinese supplier presents distinct advantages. These include access to advanced manufacturing technologies, competitive pricing structures, and scalable production capabilities. Many Chinese chemical companies specialize in OLED materials and intermediates, ensuring a deep understanding of industry requirements and quality standards. Identifying a dependable 2-Bromodibenzofuran manufacturer is therefore a strategic decision for firms aiming to optimize their procurement process.

Why Choose a Verified Supplier for Your Needs?

When procuring 2-Bromodibenzofuran, buyers should prioritize suppliers who can consistently deliver on purity, quality, and timely delivery. Checking for product specifications, Certificates of Analysis (CoA), and supplier certifications is essential. Engaging with manufacturers that offer comprehensive technical support and are willing to provide samples for evaluation can further streamline the procurement process. For businesses that rely on this critical intermediate for their OLED product development and manufacturing, establishing a relationship with a trusted supplier ensures a stable and high-quality input material, thereby contributing to the overall success of their technological advancements.

In conclusion, 2-Bromodibenzofuran (CAS 86-76-0) is more than just a chemical compound; it is an enabler of advanced display technology. Its unique chemical structure and properties make it an invaluable intermediate in the synthesis of materials that power the vibrant, efficient displays of today and tomorrow. By understanding its role and strategically sourcing it from reliable manufacturers, companies can effectively leverage its potential to drive innovation in the electronic display market.