Boron, [4-​[(4-​ethyl-​3,​5-​dimethyl-​1H-​pyrrol-​2-​yl-​κN)​(4-​ethyl-​3,​5-​dimethyl-​2H-​pyrrol-​2-​ylidene-​κN)​methyl]​-​N,​N-​dimethylbenzenaminat​o]​difluoro-​, (T-​4)​- | CAS 151486-80-5

The compound Boron [4-​[(4-​ethyl-​3,5-​dimethyl-​1H-​pyrrol-​2-​yl-​κN)​(4-​ethyl-​3,5-​dimethyl-​2H-​pyrrol-​2-​ylidene-​κN)​methyl]​-​N,N-​dimethylbenzenaminate]​difluoro-​ (T-​4)- is a complex chemical structure with potential applications across various scientific fields.

Optoelectronics: This boron-containing compound can be utilized in the development of advanced optoelectronic devices, including organic light-emitting diodes (OLEDs) and photovoltaic cells. Its unique molecular structure may contribute to improved efficiency and performance in light-emitting applications. Researchers are exploring how this compound can enhance the properties of organic semiconductors for use in flexible displays and solar panels.

Fluorescent Probes: The compound's distinct chemical features make it an excellent candidate for use as a fluorescent probe in biochemical assays. By exploiting its fluorescent properties, scientists can develop diagnostic tools and imaging agents for detecting specific biomolecules or monitoring cellular processes. This is particularly useful in fields such as medical diagnostics and cellular biology, where real-time visualization is critical.

Catalysis: This boron-based compound might serve as a catalyst in various chemical reactions, particularly those requiring high specificity and efficiency. Its structure allows for potential applications in processes like polymerization, oxidation, and other organic transformations. Researchers are investigating its catalytic activity to understand how it can be applied to sustainable chemical synthesis.

Material Science: In the realm of material science, this compound may contribute to the development of novel materials with unique physical and chemical properties. By incorporating it into polymer matrices or other materials, scientists can explore its potential to enhance strength, conductivity, or thermal stability. Such advancements have implications for creating new materials for industries ranging from automotive to electronics.