carbon capture
Self-Aspiration Membrane
High-Performance Separation and Filtration
Inspired by leaf microstructures, our membrane delivers superior permeance and selectivity under low-pressure operation. It’s repairable, resilient, and engineered to minimize operational costs in gas separation and filtration systems. Compared to conventional cellulose acetate and polyimide membranes, our technology enables more efficient processing and operational longevity.
Adsorbent for CO₂ Capture
Advanced Molecular Capture Technology
With over a decade of lifespan, our organic adsorbent performs efficiently under mild conditions. It’s optimized for Direct Air Capture, pre-combustion, and post-combustion CO₂ removal, helping lower energy usage while maintaining high separation efficiency.
Proven Materials
Patented Innovation
At Leaf-Tech, our technology platform is driven by novel material science. We’ve filed two patents covering our self-aspiration membrane and advanced CO₂ adsorbent.
Built on a foundation of research and hands-on experimentation, our solutions are already creating measurable impact in industrial applications.
What We Offer
Patents Filed
Our cutting-edge membrane and adsorbent technologies are protected by multiple patents, covering unique material compositions, fabrication methods, and application-specific designs. These innovations enable higher selectivity, durability, and efficiency compared to conventional solutions, addressing critical challenges in industries such as gas separation, and carbon capture. By securing intellectual property, we ensure long-term competitive advantage and pave the way for scalable commercialization.
Pilot Deployments
We validate our technologies through real-world pilot deployments, collecting data on efficiency, lifespan, and cost-effectiveness. These results bridge the gap between lab-scale innovation and full-scale adoption.
Proprietary Know-How
Beyond patented technologies, we possess deep proprietary expertise in synthesizing advanced materials, precision fabrication techniques, and rigorous performance testing. Our in-house capabilities allow us to optimize pore structures, surface chemistries, and mechanical stability for tailored applications—whether for high-temperature gas filtration or biomedical dialysis. This know-how accelerates iterative development and ensures consistent quality in mass production.
Collaboration to co-develop
Strategic partnerships with leading universities and corporations drive technology adaptation for specific market needs. Joint projects range from fundamental material science to industrial integration. These collaborations ensure our solutions are both scientifically robust and commercially viable.