Ferrous Metal Organic Framework
| Ferrous Metal-Organic Framework | |
| Product No | NRE-17007 |
| CAS No. | 7439-89-6 |
| Formula | Fe(OH)(O2C-C6H4-CO2) |
| APS | <40µm (can be customized) |
| Molecular Weight | 229.60g/ mol |
| Purity | 99.9% |
| Density | 0.35 g/ cm3 |
| Pore Size | ~10Å |
| Form | Powder |
| Odor | Odorless |
| SSA | ~1300 m2/g (BET) |
| Color | white |
Ferrous Metal-Organic Framework
Applications:
Gas Storage and Separation Fe-MOFs are highly effective for gas storage and separation due to their high porosity and the ability to selectively adsorb specific gases. They have been studied for the storage of gases such as hydrogen, methane, and carbon dioxide. Fe-MOFs are particularly useful in carbon capture applications, where they can selectively adsorb CO₂, helping to mitigate greenhouse gas emissions.
Catalysis Fe-MOFs show excellent potential in catalysis due to the active iron centers. These frameworks can catalyze a wide range of reactions, including oxidation, reduction, C-H activation, and hydrogenation reactions. Fe-MOFs are particularly useful in heterogeneous catalysis, where they allow for easy recovery and reuse of the catalyst. For example, Fe-MOFs can catalyze the oxidation of organic compounds, such as alcohols and hydrocarbons, with high efficiency and selectivity. They are also valuable in the conversion of biomass into useful chemicals.
Magnetic Applications Fe-MOFs have magnetic properties that arise from the iron ions. These properties make them suitable for applications such as magnetic separation of compounds, magnetic resonance imaging (MRI), and magnetic drug delivery systems. The ability to manipulate the magnetic properties of Fe-MOFs allows for the development of advanced technologies in medical imaging and targeted drug delivery, where the material can be directed to specific locations within the body using an external magnetic field.
Energy Storage Fe-MOFs are being explored for their potential in energy storage applications, such as in batteries and supercapacitors. The redox activity of iron allows Fe-MOFs to be used as electrode materials in energy storage devices. Their high surface area and ability to store charge make them efficient for energy storage, while their tunable structure allows for the enhancement of performance. Research is ongoing to improve the efficiency and cycling stability of Fe-MOFs in energy storage applications.
Environmental Remediation Fe-MOFs have shown significant promise in environmental remediation. Their ability to adsorb heavy metals, organic pollutants, and dyes from water and soil makes them effective in cleaning up contaminated environments. Fe-MOFs can also be used in the degradation of organic pollutants, such as pesticides or industrial waste, through catalytic reactions. Their high surface area and redox capabilities make them ideal candidates for cleaning up polluted water and air.
