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5,15-bis-pentafluorophenyl-10-(4-aminophenyl)corrole | CAS 1228181-72-3
| Catalog Number | A14-0056 |
| Category | Calcium, Chloride and Other indicators |
| Molecular Formula | C37H17F10N5 |
| Molecular Weight | 721.56 |
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Product Introduction
5,15-bis-pentafluorophenyl-10-(4-aminophenyl)corrole is a synthetic corrole derivative characterized by its extended conjugated system and unique electronic properties. This compound features pentafluorophenyl groups that influence its absorption and emission spectra, making it suitable for use in fluorescence-based applications. The presence of an aminophenyl group allows for potential conjugation to biomolecules, supporting its role in bioimaging and molecular tracking studies.
Product Specification
Application
Product Specification
| Storage | Store at -20°C |
Application
5,15-bis-pentafluorophenyl-10-(4-aminophenyl)corrole is a versatile compound with potential applications in various scientific fields. Here are some key applications of this compound:
Photodynamic Therapy: This corrole compound can be used as a photosensitizer in photodynamic therapy (PDT), a treatment that involves activating a photosensitizer with light to produce reactive oxygen species that can kill cancer cells. Its unique chemical structure allows it to absorb specific wavelengths of light, making it effective in targeting and destroying cancerous tissues while minimizing damage to surrounding healthy cells. Researchers are exploring its applicability in treating different types of cancer, including skin and soft tissue malignancies.
Catalysis: The compound’s unique electronic characteristics make it valuable as a catalyst in redox reactions. In chemical synthesis, it can facilitate the oxidation of organic substrates, aiding in the development of green and sustainable chemical processes. Its stability and efficiency under various conditions make it an attractive choice for industrial applications where traditional catalysts might fail.
Fluorescent Probing and Sensing: Due to its conjugated system, this corrole exhibits distinctive fluorescent properties, which can be exploited in the development of fluorescent probes and sensors. It’s particularly valuable in biochemical assays where it can highlight specific biological molecules or interactions. Scientists use it to monitor biological processes in real-time, providing insights that are crucial for basic research and diagnostic applications.
Material Science: The compound’s structural integrity and functional groups make it a potential candidate for incorporation into advanced materials. It can be used to enhance the conductive and optical properties of polymers and other composites. This application is particularly promising in the development of organic electronic devices, such as OLEDs and photovoltaic cells, where high efficiency and stability are paramount.
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