2,4-Dichloro[1]benzofuro[3,2-d]pyrimidine: Powering the Next Generation of OLEDs
Discover the foundational chemical intermediate driving innovation in organic electronics and photoelectric displays.
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2,4-Dichloro[1]benzofuro[3,2-d]pyrimidine
This compound serves as a critical building block for advanced organic light-emitting diode (OLED) materials. Its unique heterocyclic structure makes it invaluable for synthesizing specialized compounds used in the development of high-performance displays and lighting solutions, contributing significantly to the field of organic electronics.
- Explore the synthesis of advanced organic electronic materials by utilizing our 2,4-dichloro[1]benzofuro[3,2-d]pyrimidine, a key component for new generations of displays.
- Leverage the chemical properties of CAS 160199-95-1 in your organic synthesis projects to create novel photoelectric materials with enhanced performance.
- As a crucial heterocyclic intermediate, this compound facilitates the creation of specialized molecules required for cutting-edge OLED applications.
- Secure a reliable supply of high-quality 2,4-dichloro[1]benzofuro[3,2-d]pyrimidine to ensure the success of your research and development in the electronic materials sector.
Key Advantages
Versatile Intermediate
The inherent reactivity and structural features of 2,4-dichloro[1]benzofuro[3,2-d]pyrimidine make it a highly versatile intermediate for a wide array of organic syntheses, particularly for complex photoelectric compounds.
OLED Material Development
Its application in constructing sophisticated OLED materials is paramount, enabling improved luminescence efficiency, color purity, and device longevity in next-generation displays and lighting technologies.
High Purity Standards
Produced to high purity standards, this chemical intermediate ensures consistent and reliable results in sensitive electronic material synthesis, crucial for achieving optimal device performance.
Key Applications
OLED Manufacturing
Essential for synthesizing emitting layer materials, host materials, and electron transport layers in OLED devices, contributing to brighter and more efficient displays.
Organic Electronics
Used in the development of various organic electronic components, including organic transistors and solar cells, capitalizing on its unique electronic properties.
Fine Chemical Synthesis
Serves as a critical precursor in the multi-step synthesis of complex organic molecules for specialized chemical and materials science applications.
Research and Development
A vital reagent for researchers exploring new frontiers in materials science, focusing on novel photoelectric and electronic functionalities.