Unlock Advanced Material Synthesis with 1-bromo-3-(4-phenylphenyl)benzene
Your essential building block for cutting-edge OLEDs and specialized chemical applications.
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1-bromo-3-(4-phenylphenyl)benzene
This compound, identified by CAS 1762-87-4, is a high-purity organic intermediate essential for developing advanced materials, particularly in the OLED sector. Its specific structure and reliable purity ensure efficient synthesis pathways.
- Leverage our high purity 1-bromo-3-(4-phenylphenyl)benzene for your critical OLED intermediate synthesis, ensuring optimal device performance.
- As a key agrochemical intermediate, this compound aids in developing new crop protection solutions.
- Discover its utility as a versatile synthesis material intermediate, enabling novel chemical reactions.
- With its pale yellow to white powder appearance, it offers ease of handling in various laboratory and industrial processes.
Key Advantages
Exceptional Purity
Achieve consistent and reliable results in your synthesis projects with our 97% min purity 1-bromo-3-(4-phenylphenyl)benzene, a crucial factor for sensitive OLED applications.
Versatile Intermediate
This compound serves as a vital building block, facilitating the creation of complex molecules used in agrochemicals and other specialized chemical sectors.
Optimized for OLEDs
The unique molecular structure of 1-bromo-3-(4-phenylphenyl)benzene (C18H13Br) makes it an indispensable OLED intermediate for enhanced electronic performance.
Key Applications
OLED Material Synthesis
Utilize this intermediate as a core component in the production of OLED materials, contributing to brighter, more efficient displays.
Agrochemical Development
Explore its role as an agrochemical intermediate for the synthesis of novel pesticides and crop protection agents.
Specialty Chemical Synthesis
Its properties make it an ideal synthesis material intermediate for a wide array of complex organic molecules.
Research and Development
Employ this compound in R&D for discovering new functional materials and chemical pathways.