The advancement in material science, particularly in the field of electronics and optoelectronics, relies heavily on the availability of precisely engineered chemical compounds. 4-Bromo-6-phenyldibenzofuran, identified by its CAS number 1010068-84-4, is a notable example of such a specialized molecule. With its chemical formula C18H11BrO and a molecular weight of 323.18 g/mol, this dibenzofuran derivative is increasingly recognized for its potential applications in high-performance materials.

One of the significant areas where this compound finds application is in the development of Organic Light-Emitting Diodes (OLEDs) and other photoelectric materials. The rigid, planar structure of the dibenzofuran core, coupled with the phenyl and bromine substituents, can influence the electronic and optical properties of organic semiconductors. Researchers actively seek this compound as a precursor or building block to synthesize new host materials, emissive layers, or charge transport materials for next-generation displays and lighting technologies. Purchasing high-purity grades of this chemical is vital for achieving optimal device performance.

Beyond OLEDs, 4-Bromo-6-phenyldibenzofuran can also serve as a versatile intermediate in the synthesis of advanced polymers and functional materials. The bromine atom facilitates further chemical modifications, allowing for the tailoring of material properties such as thermal stability, solubility, and electronic conductivity. For companies operating in material science R&D, securing a consistent supply of this chemical from reliable manufacturers is key to enabling innovation and product development.

When procuring 4-Bromo-6-phenyldibenzofuran, material scientists and procurement specialists should prioritize suppliers known for their commitment to quality and purity. Sourcing from established chemical manufacturers, particularly those based in regions like China that specialize in fine chemicals, can provide access to this compound at competitive prices, along with comprehensive technical data. This strategic sourcing ensures that material science projects have access to the critical chemical components needed to push the boundaries of technological innovation.