AI-Driven Membranes for Industrial Gas Separation
from Lab to Plant
Next generation membranes that cut energy use by 90%.
SUPPORTED BY
The Hidden Cost of Industrial Separation
Current industrial separations rely on century-old thermal distillation processes, which account for 15% of the world’s total energy consumption and 16% of global CO2 emissions.
0
%
OF THE WORLD’S ENERGY CONSUMPION
0
%
OF GLOBAL CO₂ EMISSIONS
0
B
WASTED ANNUALLY IN THE US ALONE
Tailored Membrane Technology
Our hybrid nanocomposite membranes combine computational design with advanced materials science to achieve unprecedented performance in industrial gas separation.
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AI-Driven Discovery
Algorithms identify high-performance materials in months, not decades. -
Hybrid Durability
Combines polymer processability with solid-state resilience. -
Drop-In Efficiency
90% long-term energy savings in a modular format.
Members
André Koch Liston
Material Design
BS, Chemistry (Princeton)
PhD, Chemistry (Columbia)
"I fix things."
Mani Singh
Scaling & Device Fab
BS, Chemical Eng. (IIT)
PhD, Chemical Eng. (Houston)
"Postdoctoral Research Scientist working on understanding the physics and engineering of polymeric materials for recyclability, nanotechnology, energy storage, and sustainable separation applications."
Partner with Us
We are currently accepting inquiries for industrial pilot programs and commercial partnerships.
© 2026 Separaton Inc. | New York, NY
From Lab to Plant