Description

Key Structural & Performance Features
Distinctive Cubic Crystal Structure
The cubic crystal structure of MOF-5 (KAR-F41) is more than just a defining characteristic??it’s the foundation of its exceptional performance. This well-ordered structure ensures uniformity in its properties, allowing for consistent and predictable behavior in various applications. Researchers can rely on this structural regularity to design experiments and develop processes with a high degree of accuracy.
Highly Ordered Nanoporous Architecture
The nanoporous architecture of MOF-5 (KAR-F41) is a marvel of material design. The pores are arranged in a precise, ordered manner, creating a vast network of spaces that can accommodate a wide range of molecules. This ordered arrangement facilitates efficient diffusion and adsorption, making it an ideal choice for applications where molecular transport is critical.
Exceptionally Large Surface Area
One of the most notable features of MOF-5 (KAR-F41) is its exceptionally large surface area. This large surface area provides an abundance of active sites for molecular interactions, enhancing its performance in adsorption, catalysis, and other surface-dependent processes. It’s this feature that makes it a standout material in the field of porous materials.
Ideal Gas Storage Capacity
Thanks to its highly ordered nanoporous architecture, MOF-5 (KAR-F41) offers ideal storage capacity for gas molecules such as hydrogen (H?) and methane (CH?). The pores are perfectly sized to accommodate these molecules, allowing for efficient and high-capacity storage. This makes it a promising material for advancements in energy storage, particularly in the context of clean and sustainable energy solutions.
Remarkable Activity in Organic Catalytic Reactions
MOF-5 (KAR-F41) exhibits remarkable activity in organic catalytic reactions. Its structure provides a stable and efficient platform for catalytic sites, enabling the acceleration of chemical reactions with high selectivity. This makes it a valuable tool in organic synthesis, where precise control over reaction pathways is essential.
Excellent Chemical Stability
Chemical stability is a key attribute of MOF-5 (KAR-F41), ensuring its performance and integrity in a variety of chemical environments. It can withstand exposure to different solvents, reagents, and reaction conditions, making it a durable and reliable material for long-term use in both laboratory and industrial settings.
Tunable Surface Properties
The surface properties of MOF-5 (KAR-F41) are tunable, allowing researchers and industrial users to tailor the material to specific applications. By modifying the surface chemistry, it’s possible to enhance its adsorption selectivity, catalytic activity, or compatibility with other materials, expanding its range of potential uses.
Applications
Energy Storage
Given its ideal gas storage capacity, MOF-5 (KAR-F41) is a prime candidate for energy storage applications. It can be used for the storage of hydrogen and methane, which are important fuels in the transition to clean energy. Its ability to store these gases efficiently and safely could pave the way for the development of more practical and widespread energy storage solutions.
Gas Separation
The highly ordered nanoporous architecture and tunable surface properties of MOF-5 (KAR-F41) make it suitable for gas separation processes. It can selectively adsorb specific gas molecules, allowing for the separation of mixtures into their individual components. This has applications in various industries, including natural gas processing, air separation, and carbon capture.
Catalysis Research
With its remarkable activity in organic catalytic reactions, MOF-5 (KAR-F41) is an invaluable tool in catalysis research. It can be used to study reaction mechanisms, develop new catalytic processes, and optimize existing ones. Its stability and tunability make it a versatile material for exploring a wide range of catalytic applications.
Laboratory R&D
MOF-5 (KAR-F41) is an essential material for laboratory research and development. Its well-characterized properties and reliable performance make it a standard for studying the behavior of metal-organic frameworks and their applications. It can be used in a variety of experiments, from fundamental studies on porous materials to the development of new technologies.
Industrial Applications
Beyond laboratory research, MOF-5 (KAR-F41) has the potential to make a significant impact in industrial applications. Its durability, efficiency, and tunability make it suitable for use in large-scale processes such as gas storage, catalysis, and separation. Our high-quality MOF-5 (KAR-F41) is designed to meet the rigorous demands of industrial environments.
Quality Assurance
We understand the importance of quality in science and industrial applications, which is why our MOF-5 (KAR-F41) undergoes rigorous quality control measures. Every batch is carefully synthesized and tested to ensure high purity, consistent performance, and adherence to strict quality standards. We are committed to providing you with a material that you can trust to deliver reliable results.
Conclusion
MOF-5 (KAR-F41) is a classic high-performance metal-organic framework material that offers a unique combination of structural and functional properties. From its distinctive cubic crystal structure and highly ordered nanoporous architecture to its exceptional gas storage capacity and catalytic activity, it’s a material that holds great promise for a wide range of applications.

Our commitment to quality and customer satisfaction ensures that you receive a product that meets your exact requirements. With multiple packaging options and rigorous quality control, we provide reliable support for your research and industrial endeavors. Choose MOF-5 (KAR-F41) for your next project and experience the difference that a high-quality metal-organic framework can make.