Tetrakis[4-(4-phenylphenyl)pyridine]methane: A Key Building Block for Advanced Materials and MOF Ligands
Discover the intricate structure and versatile applications of this critical organic intermediate.
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Tetrakis[4-(4-phenylphenyl)pyridine]methane
Tetrakis[4-(4-phenylphenyl)pyridine]methane, identified by CAS number 1319736-15-6, is a sophisticated organic molecule renowned for its utility as a linker in the construction of Metal-Organic Frameworks (MOFs) and Covalent Organic Frameworks (COFs). Its unique molecular architecture, featuring a central methane core symmetrically substituted with four phenylpyridine units, imparts rigidity and specific coordination properties crucial for creating porous materials.
- Explore the chemical structure of Tetrakis[4-(4-phenylphenyl)pyridine]methane to understand its potential in novel material synthesis.
- Learn about its role as a key MOF ligand in creating advanced materials with tailored properties.
- Discover its application as a COF monomer for building highly ordered porous organic frameworks.
- Understand why it's considered a vital component in organic synthesis for creating complex molecular architectures.
Advantages and Features
Structural Rigidity
The inherent rigidity of the tetraphenylmethane core, combined with the extended aromatic systems, makes this compound an excellent choice for building stable and porous frameworks, contributing to its utility as a specialty organic intermediate.
Versatile Coordination
The pyridine nitrogen atoms offer multiple coordination sites, enabling TPPM to act as a versatile ligand. This characteristic is essential for creating diverse MOF structures, supporting its use in materials science research chemicals.
High Purity Availability
Typically available with high purity levels (97% min), it ensures reliable and reproducible results in demanding synthetic procedures, a key factor when sourcing pyridine-based ligands.
Key Applications
MOF Synthesis
Used as a vital MOF ligand, enabling the creation of materials for gas storage, separation, and catalysis.
COF Synthesis
Serves as a fundamental COF monomer, crucial for constructing porous organic materials with exceptional surface areas and tunable properties.
Materials Science Research
A key component in the development of novel advanced materials, researchers leverage its unique properties for various scientific investigations.
Advanced Organic Synthesis
Its complex structure makes it a valuable intermediate in sophisticated organic synthesis pathways for creating cutting-edge chemical compounds.