Stimuli-Responsive Metal Organic Frameworks

Stimuli-Responsive Metal Organic Frameworks

Program:
IMPACCT
Award:
$972,859
Location:
College Station, Texas
Status:
ALUMNI
Project Term:
07/01/2010 - 09/30/2012
Website:

Technology Description:

A team led by three professors at Texas A&M University is developing a subset of metal organic frameworks that respond to stimuli such as small changes in temperature to trap CO2 and then release it for storage. These frameworks are a promising class of materials for carbon capture applications because their structure and chemistry can be controlled with great precision. Because the changes in temperature required to trap and release CO2 in Texas A&M's frameworks are much smaller than in other carbon capture approaches, the amount of energy or stimulus that has to be diverted from coal-fired power plants to accomplish this is greatly reduced. The team is working to alter the materials so they bind only with CO2, and are stable enough to withstand the high temperatures found in the chimneys of coal-fired power plants.

Potential Impact:

If successful, the materials developed at Texas A&M would reduce the cost of carbon capture, enabling accelerated retrofitting of existing coal-fired power plants while satisfying consumer demand for electricity.

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. Karma Sawyer
Project Contact:
Prof. Hongcai Zhou
Press and General Inquiries Email:
ARPA-E-Comms@hq.doe.gov
Project Contact Email:
zhouh@tamu.edu

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