MOF-5 (Metal-Organic Framework-5): A Revolutionary Material for Advanced Applications

MOF-5 (Metal-Organic Framework-5) is a cutting-edge material that has gained significant attention in scientific and industrial applications. Known for its high porosity, chemical stability, and exceptional adsorption capacity, it is widely used in gas storage, catalysis, and drug delivery systems. This article delves deep into the properties, applications, synthesis, and benefits, providing an in-depth understanding of its role in modern technology.

For detailed product specifications and purchasing options, visit https://www.nanochemazone.com/product/mof-5-metal-organic-framework-5/

What is MOF-5 (Metal-Organic Framework-5)?

It is a metal-organic framework composed of zinc ions coordinated with organic linkers to form a highly porous crystalline structure. Its chemical formula is C24H12O13Zn4, and it appears as a fine powder with a purity range of ≥95% to ≥99.9%. The unique structure makes it an excellent candidate for applications requiring high surface area and controlled porosity.

Key Properties

• High Porosity exhibits an extremely high surface area, making it an ideal material for gas storage and separation.
• Thermal and Chemical Stability – The stability ensures its usability in various industrial applications.
• Customizable Particle Size – Available in particle sizes ranging from 1-5 µM to 10-53 µM, with customization options.
• Exceptional Adsorption Capacity – Capable of adsorbing large volumes of gases such as hydrogen, methane, and carbon dioxide.

Applications

1. Gas Storage and Separation

It is widely recognized for its ability to store and separate gases. Due to its high porosity and large internal surface area, it is extensively used in:

• Hydrogen Storage – Enables efficient hydrogen storage for fuel cell applications.
• Carbon Capture – Helps in reducing greenhouse gas emissions by capturing CO₂ from industrial processes.
• Methane Storage – Enhances methane storage for energy applications.

2. Catalysis and Chemical Reactions

It serves as an efficient catalyst in chemical reactions due to its tunable porosity and active metal centers. It is used in:

• Organic Synthesis – Facilitates various chemical reactions, improving yield and efficiency.
• Photocatalysis – Aids in environmental applications such as pollutant degradation and water purification.

3. Drug Delivery and Biomedical Applications

The biocompatibility and high drug-loading capacity make it suitable for drug delivery systems. Key applications include:

• Targeted Drug Delivery – Enhances the controlled release of drugs in the human body.
• Biomedical Imaging – Used in contrast agents for MRI and other imaging technologies.

4. Energy Storage and Conversion

It gaining attention in energy-related applications due to its electrochemical properties:

• Supercapacitors – Improves energy storage efficiency in electronic devices.
• Battery Applications – Enhances the performance of lithium-ion batteries.

Synthesis and Preparation

The synthesis involves a solvothermal reaction where zinc nitrate reacts with terephthalic acid in a solvent. The general synthesis process includes:

1. Dissolution of Precursors – Zinc nitrate and terephthalic acid are dissolved in an organic solvent.
2. Reaction Under Controlled Conditions – The solution is heated under specific temperature and pressure conditions.
3. Crystallization and Filtration – The crystals are formed, filtered, and washed.
4. Drying and Storage – The purified powder is dried and stored under controlled conditions.

The synthesis process can be tailored to achieve desired particle sizes and purity levels.

Advantages

1. High Surface Area and Porosity

It exhibits one of the highest surface areas among metal-organic frameworks, allowing efficient gas adsorption and separation.

2. Customizable and Scalable Production

It is available in various purities (≥95%, ≥99%, ≥99.9%) and particle sizes (1-5 µM, 10-53 µM), making it suitable for different applications.

3. Stability and Durability

With excellent thermal and chemical stability, maintains its structure even under extreme conditions.

4. Eco-Friendly and Sustainable

The use in carbon capture and gas separation contributes to reducing environmental pollution and promoting sustainable industrial practices.

Frequently Asked Questions (FAQs)

1. What is the main use of MOF-5?

It is primarily used for gas storage, catalysis, drug delivery, and energy storage due to its high surface area and porosity.

2. Is MOF-5 environmentally friendly?

Yes, it is widely used in environmental applications, including carbon capture and pollutant removal, making it a sustainable material.

3. Can MOF-5 be customized for specific applications?

Yes, MOF-5 is available in different purities (≥95%, ≥99%, ≥99.9%) and particle sizes (1-5 µM, 10-53 µM), with additional customization options upon request.

4. What is the stability of MOF-5 in harsh environments?

It exhibits excellent thermal and chemical stability, making it suitable for industrial applications under extreme conditions.

5. How is MOF-5 synthesized?

MOF-5 is synthesized through a solvothermal reaction involving zinc nitrate and terephthalic acid under controlled conditions.

6. Where can I purchase MOF-5?

You can buy high-purity MOF-5 from Nanochemazone, a trusted supplier of advanced materials.

MOF-5 (Metal-Organic Framework-5) is a revolutionary material with extensive applications across multiple industries. Its high porosity, exceptional adsorption capacity, and stability make it a key component in gas storage, catalysis, drug delivery, and energy storage solutions. As research and technology continue to evolve, MOF-5 is expected to play an even greater role in scientific advancements.

For more details on specifications, availability, and pricing, visit MOF-5 Product Page.