Unveil the Future of Methane Capture with KAIGEN
Discover the cutting-edge technology behind KAIGEN's nano-molecular membrane. This breakthrough solution in CH₄ molecular sieving and separation utilizes advanced nano-graphene and zeolite multi-layers to capture methane with unparalleled efficiency.
Watch the video to explore how KAIGEN’s innovative nanotechnology is transforming sustainable energy and driving environmental progress. Start building a cleaner future with us today.
Precision Molecular Sieving for Sustainable Methane Capture
Nanomembrane molecular sieving
Our nanomembrane technology uses advanced molecular sieving to separate methane from CO₂ with unparalleled precision.
By leveraging cutting-edge nanomaterials, we achieve highly efficient gas separation, enabling the capture of methane at a molecular level.
Our innovative process enhances sustainability, providing cleaner energy solutions and reducing greenhouse gas emissions.
What Makes Our Nanomembrane Unique for Methane Capture
How our nanomembrane molecular sieving technology stands out compared to other gas separation solutions:
High-Efficiency Separation: Utilizes nanomaterials to selectively filter methane molecules with over 90% efficiency, leaving CO2 and impurities behind.
Advanced Molecular Sieving: Our precision nanotechnology enables methane capture at a molecular level, significantly improving gas separation performance.
Sustainable Impact: Reduces methane emissions while converting captured gases into clean energy resources, supporting sustainability and circular economy efforts.
Advanced Dual-Layer Nanoparticle Design
Our nanomembrane system is engineered with a two-stage nanoparticle-embedded structure that optimizes gas separation. The first layer, composed of zeolite nanoparticles and polymeric materials, selectively targets and permeates CO₂ through steric hindrance and gas adsorption mechanisms.
The second layer, designed with graphene oxide sheets and metal-organic frameworks (MOFs), focuses on methane capture, achieving permeance rates between 500-2000 GPU. This dual-layer approach enhances selectivity and efficiency, allowing for 94% methane recovery while minimizing energy consumption and ensuring sustainable gas separation for energy applications.
Precision Molecular Sieving for Sustainable Methane Capture
High-Efficiency Methane Separation
with Dual-Layer Nanomembranes
Innovative Dual-Layer Nanomembranes using molecular separation to enhance the ch4 or gas methane capture and bioconversion
Nanomembrane for Methane Capture
Our state-of-the-art nanomembrane utilizes advanced molecular sieving technology to capture methane with over 90% efficiency. This precision technology ensures that methane is selectively separated from CO₂ and other impurities, providing a clean source of energy.
Multi-Layer Nanoparticle Membranes
The innovative dual-layer structure, infused with nanoparticles, enhances gas separation performance. The first layer selectively removes CO₂, while the second layer focuses on methane, resulting in a high methane-to-product conversion efficiency with minimal energy consumption.
By integrating our nanomembrane system into various industrial applications, we are able to convert methane into clean biogas and other sustainable outputs. This approach reduces harmful emissions, supports renewable energy efforts, and contributes to a circular economy.
Sustainable Methane Solutions
Next-Gen Methane Capture with Nanomembrane Technology
Utilizing advanced nanomembrane molecular sieving, we efficiently capture methane while separating CO₂ and impurities. Our innovative dual-layer nanoparticle design enhances gas separation precision, paving the way for sustainable energy solutions that reduce emissions and convert waste gases into clean energy and valuable materials for a greener future.