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Fluorescent Dyes
BODIPY
Boron, difluoro[1-[(4-iodophenyl)(3-methyl-2H-dibenz[E,G]isoindol-1-yl-κN)methylene]-3-methyl-1H-dibenz[E,G]isoindolato-κN]-, (T-4)-

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Boron, difluoro[1-[(4-iodophenyl)(3-methyl-2H-dibenz[E,G]isoindol-1-yl-κN)methylene]-3-methyl-1H-dibenz[E,G]isoindolato-κN]-, (T-4)-

Boron, difluoro[1-[(4-iodophenyl)(3-methyl-2H-dibenz[E,G]isoindol-1-yl-κN)methylene]-3-methyl-1H-dibenz[E,G]isoindolato-κN]-, (T-4)- | CAS 1020539-61-0

Catalog Number	F01-0143
Category	BODIPY
Molecular Formula	C41H26BF2IN2
Molecular Weight	722.383

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Product Introduction

BODIPY dyes are used to generate fluorescent conjugates of proteins, nucleotides, oligonucleotides and dextrans, as well as to prepare fluorescent enzyme substrates, fatty acids, phospholipids, lipopolysaccharides, receptor ligands and polystyrene microspheres.

Product Specification
Application

Excitation	494
Emission	517
Storage	Store at -20°C

Boron difluoro[1-[(4-iodophenyl)(3-methyl-2H-dibenz[EG]isoindol-1-yl-κN)methylene]-3-methyl-1H-dibenz[EG]isoindolato-κN]- (T-4)- is a complex boron-containing compound with potential applications in various scientific fields.

Organic Light Emitting Diodes (OLEDs): This boron compound is studied for its potential use in OLED technology due to its unique electronic properties. It can act as an efficient emitter material, facilitating better color purity and brightness in display devices. The compound’s structural attributes enable researchers to manipulate electrical conductivity and luminescence characteristics for advanced optoelectronic applications.

Fluorescent Probes: The compound can be utilized in designing fluorescent probes for biological imaging and sensing. Its distinctive structural properties make it useful in producing bright and stable fluorescence signals. Researchers can integrate it into imaging systems to visualize cellular processes, detect biomolecular interactions, and monitor environmental changes at a molecular level.

Catalysis: In the field of catalysis, boron-containing compounds like this one are explored for their ability to facilitate chemical reactions. Its unique electronic configuration can enhance reaction rates and selectivity, making it a potential candidate for developing novel synthetic methodologies. By employing such a compound, scientists aim to reduce catalyst loadings and improve the efficiency of organic transformations.

Materials Science: The boron compound can be investigated for innovative applications in the development of advanced materials. Its integration into polymer matrices or nanocomposites can enhance material properties such as thermal stability, mechanical strength, and optoelectronic functionality. This contributes to the creation of new materials with potential applications in electronics, aerospace, and energy storage technologies.