5,10,15,20-Tetrakis(4-nitrophenyl)porphyrin: Synthesis, Properties, and Applications
Explore the advanced chemistry of this synthetic porphyrin for innovative material solutions.
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Tetrakis(4-nitrophenyl)porphyrin
Discover the unique chemical properties and versatile applications of Tetrakis(4-nitrophenyl)porphyrin, a critical compound in advanced materials research and development. Its distinctive molecular structure allows for specialized functionalities, making it a sought-after material for various scientific and industrial pursuits.
- Leverage the advanced capabilities of Tetrakis(4-nitrophenyl)porphyrin for your specific research needs, offering a unique chemical structure for complex syntheses.
- Explore the potential of nitrophenyl porphyrin derivatives in developing novel materials with tailored properties for emerging technologies.
- Investigate the use of CAS 22843-73-8 in advanced organic synthesis, enabling the creation of sophisticated molecular architectures.
- Utilize this synthetic porphyrin for groundbreaking research in gas capture and storage solutions, addressing environmental and industrial challenges.
Key Advantages
High Purity and Stability
Benefit from high purity levels (often exceeding 98%), ensuring reliable and reproducible results in your experiments and applications, a key aspect of advanced organic synthesis intermediates.
Versatile Chemical Reactivity
Tap into the versatile chemical reactivity of Tetrakis(4-nitrophenyl)porphyrin, making it an ideal building block for complex molecules and functional materials.
Application in Novel Technologies
Advance your projects by incorporating this porphyrin derivative into cutting-edge applications, from catalysis to environmental solutions, highlighting its role in specialty fine chemicals for research.
Key Applications
Gas Capture and Storage
This nitrophenyl porphyrin derivative shows significant promise for high-performance gas capture and storage applications, contributing to environmental technology advancements.
Iodine Absorbent Development
Its efficacy as an iodine absorbent makes it valuable in developing specialized materials for various industrial and scientific purposes.
Catalysis
The molecule's structure lends itself to catalytic applications, facilitating chemical reactions and processes in organic chemistry and beyond.
Advanced Materials Research
Serve as a foundational component in the synthesis of novel advanced materials with unique optical, electronic, or chemical properties.