5,5,5',5'-tetrafluoro-1,1',3,3',7,7',9,9',10,10'-decamethyl-5H,5'H-[2,2'-bidipyrrolo[1,2-c:2',1'-f][1,3,2]diazaborinine]-4,6'-diium-5,5'-diuide | 1268614-83-0

5,5,5',5'-tetrafluoro-1,1',3,3',7,7',9,9',10,10'-decamethyl-5H,5'H-[2,2'-bidipyrrolo[1,2-c:2',1'-f][1,3,2]diazaborinine]-4,6'-diium-5,5'-diuide is an advanced organic compound featuring a complex structure of two pyrrolo[1,2-c:2',1'-f]diazaborinine units, which are bridged by a tetrafluorinated core. This compound is characterized by its high stability and unique electronic properties, derived from the presence of both fluorine atoms and the diazaborinine moiety. The combination of its aromatic nature and the electron-withdrawing effects of the fluorine substituents contributes to its strong electronic and photophysical characteristics, making it useful in various cutting-edge applications.

One prominent application of this compound is in organic electronics, specifically in organic light-emitting diodes (OLEDs) and organic solar cells. The compound's strong absorption and emission properties, along with its excellent photostability, make it a potential candidate for use in OLEDs, where it can enhance efficiency and performance. The unique molecular structure allows for the fine-tuning of its optical properties, which can lead to improved light output and energy efficiency in display and lighting technologies. Additionally, its ability to absorb solar radiation makes it a promising material for organic photovoltaics, where it can help convert light energy into electricity efficiently.

Another application of this compound is in the development of fluorescent sensors for chemical and biological detection. Its high fluorescence quantum yield and sensitivity to environmental changes make it suitable as a probe for detecting ions, biomolecules, or other target analytes. By modifying the compound to respond to specific stimuli, it can be used in sensitive and selective detection methods, which are valuable in applications like environmental monitoring, chemical analysis, and diagnostic imaging. The compound’s ability to provide real-time feedback through fluorescence allows for precise monitoring of chemical and biological processes.

This compound also has potential uses in catalysis, particularly in facilitating organic reactions. The presence of the boron-containing core provides Lewis acidic properties, making the compound an effective catalyst for certain reactions, such as polymerization and other organic transformations. Its stability and reactivity allow it to act as a catalyst activator, helping to enhance reaction rates and selectivity in synthetic chemistry. This ability could be exploited for the development of more efficient and sustainable chemical processes, especially in industries that rely on complex organic synthesis.

Finally, 5,5,5',5'-tetrafluoro-1,1',3,3',7,7',9,9',10,10'-decamethyl-5H,5'H-[2,2'-bidipyrrolo[1,2-c:2',1'-f][1,3,2]diazaborinine]-4,6'-diium-5,5'-diuide has potential applications in materials science, particularly in the development of new advanced materials with specialized electronic and optical properties. Due to its stable and well-defined molecular structure, this compound could be utilized in the fabrication of materials with tailored electronic, optical, and magnetic properties. Such materials could be applied in next-generation electronic devices, sensors, or even energy storage systems, where enhanced performance and novel functionality are desired.