N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide: A Key MOF Precursor

Unlock advanced material properties with our high-purity perylene-based diamide, essential for MOF synthesis.

Product Core Value

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide

This specialized chemical compound, known for its high purity, serves as a critical building block in the field of advanced materials, particularly for the synthesis of Metal-Organic Frameworks (MOFs). Its unique structure, featuring perylene tetracarboxylic acid backbone functionalized with pyridine groups, makes it an excellent choice for creating complex porous structures with tailored properties.

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid Diamide MOF synthesis: Facilitates the creation of novel MOF structures with high efficiency.
Organic chemistry MOF building blocks: Essential component for researchers and manufacturers developing next-generation porous materials.
CAS 136847-29-5 metal organic frameworks: A precisely identified chemical intermediate crucial for reproducible MOF fabrication.
N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid Diamide solubility DMF DMSO: Demonstrates good solubility in common organic solvents like DMF and DMSO, enabling versatile reaction conditions.

Product Advantages

High Purity and Reliability

Ensures consistent results in your N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid Diamide MOF synthesis, with a guaranteed purity of 97% min.

Versatile Solubility

Offers excellent N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid Diamide solubility DMF DMSO, allowing for flexible integration into various synthetic pathways.

Structural Versatility

The pyridine functionalization makes it a valuable component for designing MOFs with specific catalytic or adsorption properties, highlighting its role as one of the key organic chemistry MOF building blocks.

Key Applications

Metal-Organic Frameworks (MOF) Construction

Serves as a primary ligand for constructing diverse MOF architectures, crucial for applications in gas storage, catalysis, and separation.

Advanced Organic Synthesis

Utilized as a specialty intermediate in complex organic synthesis projects requiring specialized perylene-based structures.

Materials Science Research

A key compound for researchers exploring new functional materials and understanding structure-property relationships in porous systems.

Catalysis Development

Its pyridine groups can coordinate with metal centers, potentially enhancing catalytic activity in MOF-based catalytic systems.

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide: A Key MOF Precursor

Product Core Value

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide

Product Advantages

High Purity and Reliability

Versatile Solubility

Structural Versatility

Key Applications

Metal-Organic Frameworks (MOF) Construction

Advanced Organic Synthesis

Materials Science Research

Catalysis Development

Related Technical Articles & Resources

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide: A Versatile Ligand for MOF Innovation

Leveraging Pyridine-Functionalized Perylene Diamides for Advanced MOF Applications

Perylene Tetracarboxylic Acid Diamides: Key Components for Functional MOFs

The Impact of Perylene-Based Ligands in Advanced MOF Architectures

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide: A Key MOF Precursor

Product Core Value

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide

Product Advantages

High Purity and Reliability

Versatile Solubility

Structural Versatility

Key Applications

Metal-Organic Frameworks (MOF) Construction

Advanced Organic Synthesis

Materials Science Research

Catalysis Development

Related Technical Articles & Resources

N,N'-Di(pyrid-4-yl)-perylentetracarbonic Acid, Diamide: A Versatile Ligand for MOF Innovation

Leveraging Pyridine-Functionalized Perylene Diamides for Advanced MOF Applications

Perylene Tetracarboxylic Acid Diamides: Key Components for Functional MOFs

The Impact of Perylene-Based Ligands in Advanced MOF Architectures

Related Topics