Advancing Material Science with 2,9-Bis[p-(formyl)phenyl]-1,10-phenanthroline
Unlock the potential of advanced materials with this crucial organic building block for COFs and MOFs.
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2,9-Bis[p-(formyl)phenyl]-1,10-phenanthroline
This versatile organic molecule is a cornerstone in the synthesis of advanced porous materials, notably Covalent Organic Frameworks (COFs) and Metal-Organic Frameworks (MOFs). Its unique chemical structure, featuring both aldehyde and phenanthroline functionalities, makes it an ideal linker for constructing complex, ordered molecular architectures.
- Leveraging the 2,9-Bis[p-(formyl)phenyl]-1,10-phenanthroline COF synthesis capabilities, researchers can develop novel materials with tailored properties.
- The formylphenyl phenanthroline linker for MOFs allows for precise control over pore size and chemical functionality in the resulting frameworks.
- As an aldehyde functionalized phenanthroline for materials science, it facilitates diverse chemical reactions for material innovation.
- The CAS 120085-99-6 COF building block is instrumental in creating high-performance materials for catalysis and gas adsorption.
Key Advantages
Versatile Linker
The presence of aldehyde groups allows for facile Schiff-base condensation reactions, a key step in many phenanthroline derivative for covalent organic frameworks syntheses.
Structural Precision
The rigid phenanthroline core and strategically placed formyl groups enable the design of highly ordered and predictable porous structures in COFs and MOFs.
Broad Applicability
Its utility extends to catalysis, sensing, gas separation, and energy storage, making it a valuable component for cutting-edge research and development.
Key Applications
Covalent Organic Frameworks (COFs)
This compound is a primary monomer for building COFs, enabling applications in catalysis, gas storage, and sensing through precise molecular design.
Metal-Organic Frameworks (MOFs)
As a ligand, it contributes to the formation of MOFs with unique porous structures and functionalities, crucial for applications in chemical separation and catalysis.
Advanced Catalysis
Materials derived from this linker can exhibit enhanced catalytic activity due to their high surface area and tunable electronic properties.
Gas Storage and Separation
The porous nature of COFs and MOFs synthesized using this building block makes them highly effective for storing and separating various gases.