Renewables-Based Catalytic Ammonia Production

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Program:
REFUEL
Award:
$3,111,904
Location:
Research Triangle Park, North Carolina
Status:
ALUMNI
Project Term:
04/10/2017 - 10/09/2020
Website:

Technology Description:

Research Triangle Institute (RTI) will develop a catalytic technology for converting renewable energy, water, and air into ammonia. Their work focuses on three innovations: the development of an ammonia synthesis catalyst for improved reactions, refinement of the ammonia synthesis to handle intermittent loads, and optimized and scalable technologies for air separation to produce high-purity nitrogen. Their ammonia synthesis catalyst features increased surface area, high dispersion, and high thermal stability – enabling the system to operate at much lower temperatures and pressures, lowering energy consumption by 35%. It also reduces the balance of plant costs by simplifying the design and decreasing refrigeration loads. By using low-cost nitrogen purification techniques, they aim to lower the cost and amount of nitrogen required. When completed, the project will result in a small-scale ammonia synthesis system that is economically viable and can start and stop in synchronization with intermittent renewable power sources.

Potential Impact:

If successful, developments from REFUEL projects will enable energy generated from domestic, renewable resources to increase fuel diversity in the transportation sector in a cost-effective and efficient way.

Security:

The U.S. transportation sector is heavily dependent on petroleum for its energy. Increasing the diversity of energy-dense liquid fuels would bolster energy security and help reduce energy imports.

Environment:

Liquid fuels created using energy from renewable resources are carbon-neutral, helping reduce transportation sector emissions.

Economy:

Fuel diversity reduces exposure to price volatility. By storing energy in hydrogen-rich liquid fuels instead of pure hydrogen in liquid or gaseous form, transportation costs can be greatly reduced, helping make CNLFs cost-competitive with traditional fuels.

Contact

ARPA-E Program Director:
Dr. Grigorii Soloveichik
Project Contact:
Dr. Sameer Parvathikar
Press and General Inquiries Email:
ARPA-E-Comms@hq.doe.gov
Project Contact Email:
sparvathikar@rti.org

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• Gas Technology Institute (GTI) - Dimethyl Ether Synthesis from Renewables
• Giner - Anion Exchange Membrane Ammonia Production
• Molecule Works - Electrochemical Membrane Reactor for Ammonia
• Opus 12 - Carbon Dioxide Conversion to Ethanol
• Rensselaer Polytechnic Institute (RPI) - H2 From Thermal Catalytic Ammonia Decomposition
• Research Triangle Institute (RTI) - Renewables-Based Catalytic Ammonia Production
• RTI International - Next-Generation Ammonia System Integration Utilizing Intermittent Renewable Power
• SAFCell - Electrochemical Ammonia Conversion
• Skyre - Carbon Dioxide to Dimethyl Ether
• Storagenergy Technologies - Solid-State Alkaline Electrolyzer Ammonia Synthesis
• University of Delaware (UD) - Direct Ammonia Fuel Cells
• University of Minnesota (UMN) - Wind Energy to Ammonia Synthesis
• West Virginia University Research Corporation (WVURC) - Microwave-Plasma Ammonia Synthesis
• Wichita State University - Alkaline Membrane-Based Ammonia Electrosynthesis

Release Date:
04/26/2016