Unlocking the Potential: 4,4'-[(4-Bromophenyl)imino]dibenzaldehyde CAS 167859-41-8 in Advanced Chemistry
Discover the properties and applications of a key organic intermediate for cutting-edge material science and synthesis.
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4,4'-[(4-Bromophenyl)imino]dibenzaldehyde
This chemical compound, identified by CAS number 167859-41-8, is a crucial building block in organic synthesis. With its distinct structure, it serves as a vital intermediate in the development of advanced materials, particularly for applications in the field of OLED technology. Its purity of 97%+ ensures reliable performance in demanding chemical processes.
- High Purity Intermediate: Featuring a purity of 97%+, this compound is essential for applications requiring precise chemical compositions, making it a valuable asset for manufacturers seeking reliable organic intermediates for OLED materials.
- Key Chemical Properties: Possessing a molecular formula of C20H14BrNO2 and a molecular weight of 380.24, its defined structure and a melting point of 217 °C underscore its stability and suitability for various synthetic routes.
- Versatile Applications: Beyond OLEDs, this benzaldehyde derivative acts as a fundamental component in complex organic synthesis, enabling the creation of novel molecules and materials.
- Reliable Synthesis Partner: As a key player in chemical synthesis, understanding the properties of this compound is crucial for optimizing reaction yields and product quality.
Advantages Provided by the Product
Enhanced Material Performance
Leveraging 4,4'-[(4-bromophenyl)imino]dibenzaldehyde CAS 167859-41-8 in your synthesis can lead to materials with improved electronic and optical properties, crucial for next-generation displays and lighting.
Streamlined Synthesis Processes
As a well-characterized organic intermediate, its predictable reactivity and purity help streamline complex chemical processes, reducing development time and costs.
Broad Applicability in Research
Researchers exploring new frontiers in material science will find this compound invaluable for developing novel compounds, aiding in the quest for advanced functional materials.
Key Applications
OLED Material Precursors
This compound serves as a critical precursor in the synthesis of organic light-emitting diode (OLED) materials, contributing to advancements in display technology and solid-state lighting.
Organic Synthesis
Its versatile chemical structure makes it a foundational element for creating a wide array of complex organic molecules, supporting diverse research and industrial applications.
Specialty Chemicals
As a refined organic compound, it finds its place in the development of specialty chemicals, catering to niche markets with specific performance requirements.
Advanced Material Development
Its unique properties make it a candidate for research into novel materials with tailored electronic, optical, or structural characteristics.