Low Regeneration Energy
Some MOFs release the captured CO₂ at relatively low temperatures or with minimal energy input compared to conventional solvents like amines. This makes the capture–release cycle more energy-efficient.
Metal-Organic Frameworks (MOFs) are next-generation porous materials that combine ultra-high surface area, tunable pore structures, and unmatched selectivity. Built from metal ions and organic linkers, MOFs unlock breakthrough solutions in CO₂ capture, gas separation, energy storage and environmental technologies.
With their lightweight yet powerful crystalline networks, MOFs outperform conventional adsorbents like zeolites or activated carbons. From cutting industrial emissions to enabling sustainable energy systems, MOFs are redefining the future of clean technology.
Scalable. Efficient. Sustainable.
Some MOFs release the captured CO₂ at relatively low temperatures or with minimal energy input compared to conventional solvents like amines. This makes the capture–release cycle more energy-efficient.
MOFs have some of the highest surface areas of any known material—up to 7,000 m²/g. This allows them to adsorb large amounts of CO₂ relative to their weight, making them highly efficient.
Many modern MOFs are stable under high temperatures and in humid or chemically harsh environments -important for real-world industrial use.
MOFs can be designed to have a strong affinity for CO₂ molecules, even in the presence of other competing gases. This improves the purity of captured CO₂ and reduces the need for post-separation steps.
The size, shape, and chemical functionality of MOFs can be precisely engineered. This tunability enables selective adsorption of CO₂ over other gases (like N₂ or H₂O), which is critical for capturing CO₂ from flue gases or ambient air.
