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

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

Boron, difluoro[3-methyl-1-[(3-methyl-2H-dibenz[E,G]isoindol-1-yl-κN)phenylmethylene]-1H-dibenz[E,G]isoindolato-κN]-, (T-4)- | CAS 1020539-60-9

Catalog Number	F01-0142
Category	BODIPY
Molecular Formula	C41H27BF2N2
Molecular Weight	596.487

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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[3-methyl-1-[(3-methyl-2H-dibenz[EG]isoindol-1-yl-κN)phenylmethylene]-1H-dibenz[EG]isoindolato-κN]- (T-4)- is a compound with potential applications in various scientific fields. Here are some key applications of this compound:

Optoelectronics: This compound has promising applications in the field of optoelectronics, particularly as a component of organic light-emitting diodes (OLEDs). It exhibits strong luminescence properties, making it suitable for use in display and lighting technologies. Researchers are investigating its stability and efficiency to enhance the performance of OLED devices.

Fluorescent Probes: In biochemical research, this boron compound can be used as a fluorescent probe due to its unique light-emitting characteristics. It is valuable for imaging applications where visualizing specific biological molecules within cells is crucial. Scientists utilize it to study molecular interactions and cellular dynamics in real-time.

Advanced Materials: The structural configuration of this compound allows for potential use in developing advanced materials with unique properties. These materials could be applied in fields such as sensors and photodetectors, capitalizing on the compound’s optoelectronic attributes. Researchers explore the material’s ability to alter its electrical conductivity or optical properties under various conditions.

Chemical Catalysis: This boron-based compound holds promise as a catalyst in organic synthesis processes. Its ability to influence reaction pathways can lead to the development of more efficient and selective chemical transformations. Scientists are working on harnessing its catalytic properties to create novel reactions for producing complex organic molecules.