Unlock the Potential of Dibrominated Triphenylamine Derivatives
Explore the critical role of 4,4'-Dibromo-4''-phenyltriphenylamine in advanced material synthesis and electronic applications.
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4,4'-Dibromo-4''-phenyltriphenylamine
This high-purity organic intermediate serves as a crucial building block for novel functional materials and advanced electronic components, particularly in the realm of Organic Light-Emitting Diodes (OLEDs). Its unique structure, featuring dibrominated phenyl groups attached to a triphenylamine core, makes it indispensable for precise molecular engineering in materials science.
- Understanding the properties of dibrominated triphenylamine derivatives is key for efficient material design. With a purity of 98% min and the CAS number 884530-69-2, this compound offers reliable performance.
- The synthesis of OLED materials often requires specialized organic intermediates. 4,4'-Dibromo-4''-phenyltriphenylamine is integral to creating materials with specific optoelectronic characteristics.
- Exploring the applications of organic intermediates in electronic devices reveals the demand for compounds like this dibrominated triphenylamine for enhanced performance and stability.
- Sourcing high purity organic chemicals is vital for research and development. We provide reliable access to this critical chemical reagent for your material science projects.
Key Advantages
Enhanced Electronic Properties
The strategic placement of bromine atoms and the triphenylamine core allows for fine-tuning of electronic properties, essential for efficient OLED material synthesis.
Versatile Building Block
As a versatile organic intermediate for OLEDs, it enables the creation of complex molecular architectures with tailored photophysical behavior.
Guaranteed Purity and Quality
We ensure a high purity level (98% min) for this compound, critical for reproducible results in research and manufacturing, supporting your need to buy 4,4'-dibromo-4''-phenyltriphenylamine online.
Key Applications
OLED Devices
Crucial for the development of emissive layers and charge transport materials in OLED displays and lighting, leveraging triphenylamine derivatives synthesis.
Organic Photovoltaics (OPVs)
Used in the synthesis of donor or acceptor materials to improve the efficiency and stability of organic solar cells.
Organic Field-Effect Transistors (OFETs)
Serves as a precursor for semiconductor materials in flexible electronic devices.
Advanced Functional Materials
Its reactive bromine sites allow for further functionalization, creating novel materials with unique optical and electronic properties.