Synthetic Catalysts for CO2 Storage

Default ARPA-E Project Image

Program:
IMPACCT
Award:
$3,611,376
Location:
Livermore, California
Status:
ALUMNI
Project Term:
08/15/2010 - 12/31/2014
Website:

Technology Description:

Lawrence Livermore National Laboratory (LLNL) is designing a process to pull CO2 out of the exhaust gas of coal-fired power plants so it can be transported, stored, or utilized elsewhere. Human lungs rely on an enzyme known as carbonic anhydrase to help separate CO2 from our blood and tissue as part of the normal breathing process. LLNL is designing a synthetic catalyst with the same function as this enzyme. The catalyst can be used to quickly capture CO2 from coal exhaust, just as the natural enzyme does in our lungs. LLNL is also developing a method of encapsulating chemical solvents in permeable microspheres that will greatly increase the speed of binding of CO2. The goal of the project is an industry-ready chemical vehicle that can withstand the harsh environments found in exhaust gas and enable new, simple process designs requiring less capital investment.

Potential Impact:

If successful, LLNL's synthetic catalyst could significantly improve the speed of the reactions that draw CO2 out of coal exhaust gas, improving the cost and efficiency of carbon capture and storage.

Security:

Enabling continued use of domestic coal for electricity generation will preserve the stability of the electric grid.

Environment:

Carbon capture technology could prevent more than 800 million tons of CO2 from being emitted into the atmosphere each year.

Economy:

Enabling cost-effective carbon capture systems could accelerate their adoption at existing power plants.

Contact

ARPA-E Program Director:
Dr. Ramon Gonzalez
Project Contact:
Dr. Roger Aines
Press and General Inquiries Email:
ARPA-E-Comms@hq.doe.gov
Project Contact Email:
aines@llnl.gov

Partners

The Babcock & Wilcox Company
University of Illinois, Urbana Champaign

Related Projects

• Alliant Techsystems (ATK) - Supersonic Technology for CO2 Capture
• Codexis - Better Enzymes for Carbon Capture
• Columbia University - Chemically Accelerated Carbon Mineralization
• General Electric (GE) Global Research - CO2 Capture with Liquid-to-Solid Absorbents
• Georgia Tech Research Corporation - Composite Membranes for CO2 Capture
• Lawrence Livermore National Laboratory (LLNL) - Synthetic Catalysts for CO2 Storage
• Massachusetts Institute of Technology (MIT) - CO2 Capture Using Electrical Energy
• Oak Ridge National Laboratory (ORNL) - High Surface-Area CO2 Sponge
• Research Triangle Institute (RTI) - CO2 Capture and Regeneration at Low Temperatures
• Sustainable Energy Solutions (SES) - Capturing CO2 from Exhaust Gas
• Texas A&M University - Stimuli-Responsive Metal Organic Frameworks
• University of California, Berkeley (UC Berkeley) - Metal Organic Framework Research
• University of Colorado, Boulder (CU-Boulder) - Gelled Ionic Liquid-Based Membranes
• University of Kentucky - Hybrid Solvent-Membrane CO2 Capture
• University of Notre Dame - Phase-Changing Ionic Liquids

Release Date:
02/07/2009