2,6-Di(3-carboxyphenyl)pyridine: A Key Intermediate for Advanced Materials
Unlock the potential of Metal-Organic Frameworks and Organic Synthesis with this high-purity heterocyclic compound.
Get a Quote & SampleProduct Core Value
2,6-Di(3-carboxyphenyl)pyridine
As a crucial component in the realm of advanced materials, 2,6-Di(3-carboxyphenyl)pyridine stands out for its unique chemical structure and versatile applications. Its precisely arranged carboxylic acid groups on a pyridine core make it an ideal candidate for constructing complex porous frameworks, including Metal-Organic Frameworks (MOFs) and Covalent Organic Frameworks (COFs). These materials are at the forefront of innovation in areas such as gas storage, catalysis, and separation technologies. Furthermore, its role as a high-purity organic intermediate makes it invaluable for researchers and manufacturers engaged in custom chemical synthesis and the development of novel organic compounds. The consistent quality and reliable supply ensure that your research and development projects can proceed with confidence.
- Unlock the potential for custom synthesis by leveraging this versatile organic building block in your next project.
- Discover efficient MOF synthesis routes using high-purity 2,6-Di(3-carboxyphenyl)pyridine as a primary linker.
- Explore novel applications in advanced materials by incorporating this key heterocyclic compound into your framework designs.
- Ensure project success with reliable sourcing of specialty chemical intermediates tailored for demanding research and industrial needs.
Advantages Offered
Structural Versatility
The pyridine core coupled with two carboxyphenyl groups provides a rigid and functionalizable platform, essential for building stable and porous structures in MOF synthesis.
High Purity
With a minimum purity of 97%, this compound is ideal for applications where precise stoichiometry and reaction control are critical for achieving desired material properties and facilitating accurate organic synthesis.
Broad Applicability
Serving as a vital intermediate, it enables advancements in areas like catalysis, separation science, and pharmaceuticals, demonstrating its broad utility in fine chemical industries.
Key Applications
MOF Synthesis
As a primary linker, it forms the structural backbone of Metal-Organic Frameworks, offering tailored porosity and surface area for advanced applications.
COF Synthesis
Its reactive functional groups facilitate the formation of Covalent Organic Frameworks, contributing to the development of new porous materials with unique properties.
Organic Synthesis Intermediate
Utilized as a building block in complex organic synthesis pathways, enabling the creation of novel molecules with potential pharmaceutical or material science applications.
Research & Development
Essential for academic and industrial research, supporting investigations into new materials, catalysts, and advanced chemical processes.