Unlock Advanced Electronics with Fluoro-Indenylidene Malononitrile
A key building block for high-efficiency organic solar cells and optoelectronic applications.
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2-(6-Fluoro-3-oxo-2,3-dihydro-1H-inden-1-ylidene)malononitrile
This advanced chemical intermediate is a mono-fluorinated electron deficient end group crucial for the synthesis of highly efficient non-fullerene acceptors (NFAs). Its unique structure facilitates intermolecular interactions, such as F···S and F···H bonds, which are vital for extending the absorption of targeted NFAs into the near-infrared (NIR) spectrum, a key advancement in solar cell technology.
- Discover the potential of fluoro-indenylidene malononitrile for NFA synthesis in your next project. The precise molecular design ensures optimal performance in advanced organic electronic devices.
- Access high purity 507484-54-0 chemical intermediate for demanding applications in materials science and organic chemistry research.
- Enable the synthesis of non-fullerene acceptors with fluorinated end groups, a critical step in developing next-generation solar energy conversion technologies.
- Explore new possibilities in organic solar cell materials development with this versatile and high-performance compound.
Key Product Advantages
Enhanced Electron Deficiency
Leverage the electron deficient nature of this molecule to improve charge transport properties in organic electronic devices, contributing to higher overall efficiency.
NIR Absorption Extension
Utilize this compound to facilitate the synthesis of materials that absorb light further into the near-infrared spectrum, capturing more solar energy.
High Purity and Reliability
Count on the consistent quality and high purity (>97%) of this chemical intermediate for reproducible and successful research and manufacturing outcomes.
Key Applications
Non-Fullerene Acceptor Synthesis
A primary use is in the synthesis of advanced NFAs, crucial for improving the performance and efficiency of organic solar cells.
OLED Materials
Serves as a valuable building block for developing new materials used in Organic Light-Emitting Diodes (OLEDs), contributing to brighter and more efficient displays.
Chemical Synthesis
Acts as a versatile chemical intermediate in various organic synthesis pathways, enabling the creation of complex molecules for diverse applications.
Optoelectronic Materials
Its unique properties make it suitable for research and development in a broad range of optoelectronic materials, pushing the boundaries of device performance.