Unlock Advanced Material Properties with 4,4'-Diamino-3,3'-Biphenyldisulfonic Acid
Discover the potential of this key MOF linker for creating innovative porous materials.
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4,4'-Diamino-3,3'-Biphenyldisulfonic Acid
This compound is a vital component in the synthesis of advanced porous materials, particularly Metal-Organic Frameworks (MOFs). Its unique chemical structure, featuring sulfonic acid groups and amine functionalities, makes it an excellent organic linker for constructing highly porous and stable frameworks with diverse applications.
- Explore the synthesis of biphenyldisulfonic acid derivatives for novel material development and understand its role as a crucial MOF linker.
- Achieve high purity of 97% min in your material synthesis with this meticulously prepared chemical intermediate.
- Leverage the specific properties of 4,4'-Diamino-3,3'-Biphenyldisulfonic Acid CAS 3365-90-0 in your research and industrial applications.
- Understand the importance of sulfonic acid MOFs linkers in creating materials for gas storage and separation.
Advantages You Gain
Enhanced Porosity in MOFs
Utilize this compound as a key MOF linker to engineer materials with exceptional porosity, facilitating applications in gas storage and separation.
Versatile Chemical Intermediate
Its dual amine and sulfonic acid functionalities offer broad possibilities for organic synthesis and the development of specialized chemical intermediates.
Reliable Material Performance
With a high purity of 97% min, this product ensures consistent and reliable performance in demanding material science applications.
Key Applications
Metal-Organic Frameworks (MOFs)
A fundamental building block for constructing MOFs, enabling tailored porosity for gas adsorption and catalysis research.
Advanced Porous Materials
Essential for creating novel porous materials with applications ranging from filtration to energy storage, driven by its role as a specialized linker.
Organic Synthesis
Serves as a valuable intermediate in complex organic synthesis pathways, offering unique functional groups for chemical modification.
Material Science Research
Supports cutting-edge research in material science, particularly in the design and synthesis of functional organic-inorganic hybrid materials.