Project Selections for FOA 2614: Carbon Management (Round 1)

 

AREA OF INTEREST (AOI)-1 – CARBON CONVERSION TECHNOLOGY

AOI-1A – Lab-Scale Testing of Mineralization Systems to Generate Commercial Products

Biomolecular Regulated Carbonation Pathway to Process Calcium-rich Alkaline Industrial Wastes into Supplementary Cementitious Materials (BioCarb) – University of Alabama (Tuscaloosa, Alabama) UA), in partnership with the University of Tennessee Knoxville, National Renewable Energy Laboratory, and Sutterlin Research LLC, will develop a low-cost and eco-friendly biomolecule-regulated carbonation system. The system will convert calcium-rich, alkaline construction and industrial wastes, such as recycled concrete fines, cement kiln dust, and high calcium fly ash, into carbon-negative and carbonate-rich supplementary cementitious materials, and then permanently store CO₂ in the produced materials.

DOE Funding: $2,000,000
Non-DOE Funding: $500,002
Total Value: $2,500,002

 

Converting CO₂ and Alkaline Solid Wastes to Carbon-Negative Alternative Cement for Precast Concrete Units – The Washington University (St. Louis, Missouri) intends to develop an innovative and economical process for mineralizing CO₂ by producing a carbon-negative alternative cement using a CO₂-derived cement-forming chemical and alkaline solid wastes. The process will deliver a laboratory-scale, prototype system capable of converting 10 kg of CO₂ per day for making concrete.

DOE Funding: $2,000,000
Non-DOE Funding: $502,159
Total Value: $2,502,159

 

Development of an Advanced CO₂ Mineralization Technology for Coproduction of Value-Added Carbonate and Fertilizer Products – Board of Trustees of the University of Illinois (Champaign, Illinois) plans to develop an advanced technology for the mineralization of carbon dioxide (CO₂₎ from industrial sources. The process will use dry or wet flue gas desulfurization byproducts for coproduction of value-added precipitated calcium carbonate and sulfate fertilizer products and validate its technical and economic competitiveness and environmental sustainability.

DOE Funding: $ 1,994,739
Non-DOE Funding: $ 502,845
Total Value: $ 2,497,584

 

Electrochemical-Enabled Carbon Dioxide Mineralization of Natural Brines and Wastes to Enable Carbon-Negative Value-Added Products – Ohio University (Athens, Ohio) plans to explore electrochemical CO₂ mineralization technologies, combined with low-carbon electrical power, to simultaneously offer a potential pathway to sequester CO₂ and generate value-added building products.

DOE Funding: $2,000,000
Non-DOE Funding: $500,000
Total Value: $2,500,000

 

AOI-2 – CARBON DIOXIDE REMOVAL TECHNOLOGY

AOI-2A – Carbon Dioxide Removal R&D: Bench-Scale Testing of Structured Material Systems, or Component Designs for Optimized Direct Air Capture

Advanced Engineered Structures for High Performance Direct Air Capture System – TDA Research, Inc. (Wheat Ridge, Colorado), in partnership with GE Research, plans to develop a structured sorbent cell that can be economically produced at large-scale. The thickness of the sorbent layer and the geometry will be optimized to reduce the pressure drop and improve the heat transfer rate, thereby increasing the CO₂ productivity.

DOE Funding: $1,500,000
Non-DOE Funding: $474,000
Total Value: $1,974,000

 

Advancing a Low-Temperature, Low-Cost Direct Air Capture System Based on Organic Chemistry – Holocene Climate Corporation (San Francisco, California) plans to partner with Oak Ridge National Laboratory (ORNL) to conduct bench-scale testing of a new optimized direct air capture system using amino acids and guanidine compounds, a chemical process invented at ORNL. Holocene aims to use ORNL’s chemistry to further develop and deploy the technology on a commercial scale.

DOE Funding: $1,500,000
Non-DOE Funding: $420,000
Total Value: $1,920,000

 

Amine Infused ePTFE/SiO₂ Laminate Structured Sorbents as an Advanced Direct Air Capture System – Georgia Tech Research Corporation (Atlanta, Georgia) intends to develop novel CO₂ sorbent contactors and direct air capture process technologies, using polyethyleneimine-infused expanded polytetrafluoroethylene/silica laminate sheets.

DOE Funding: $1,326,312
Non-DOE Funding: $332,105
Total Value: $1,658,417

 

Bench-Scale Development of Ionic Liquid Catalyzed High-Capacity Structured Sorbents – Susteon Inc. (Cary, North Carolina) plans to develop a high-capacity structured direct air capture sorbent material system to make significant progress towards reaching DOE’s Carbon Negative Shot target of less than $100/net tonne of CO₂ removed.

DOE Funding: $1,500,000
Non-DOE Funding: $375,000
Total Value: $1,875,000

 

AOI-2B – Carbon Dioxide Removal R&D: Bench-Scale Testing of Optimized Direct Air Capture Integrated Processes

3D Printed Engineered Structures for High Performance Direct Air Capture System – TDA Research, Inc. (Wheat Ridge, Colorado), in partnership with Schlumberger and Missouri University of Science and Technology, intends to develop a structured sorbent cell that can be economically produced at large-scale. The primary focus of the project will be to build the structured sorbent cell/unit with the desired mass and heat transfer capability.

DOE Funding: $2,999,956
Non-DOE Funding: $750,000
Total Value: $3,749,956

 

An Integrated and Continuous Bench-Scale Passive DAC Demonstration – Research Triangle Institute (Research Triangle Park, North Carolina), in partnership with Creare and GE Research, intends to design, build and test an integrated bench-scale contactor process for continuous direct air capture of CO₂.

DOE Funding: $3,000,000
Non-DOE Funding: $750,000
Total Value: $3,750,000

 

Integrated Bench-Scale Testing of a Structured Sorbent for Direct Air Capture – Susteon Inc. (Cary, North Carolina) will develop and test an integrated bench-scale direct air capture prototype test unit using a novel structured sorbent with an ultimate cost target of <$100/ton CO₂ captured, based on an inexpensive sodium carbonate-based sorbent dispersed on a porous alumina support.

DOE Funding: $3,000,000
Non-DOE Funding: $750,000
Total Value: $3,750,000

 

Negative-Emissions Enabled Direct Air Capture with Coupled Electro-Production of Hydrogen at 5 kg-per-hour Scale – University of Kentucky Research Foundation (Lexington, Kentucky) intends to develop an intensified and cost-effective net-negative emissions process for the direct air capture of CO₂ at a 5 kg-per-hour scale. The process builds upon the University’s technology on electrochemically regenerated hydroxide solvent for direct air capture and hydrogen co-production. It includes further integration with renewable power from solar photovoltaics to decouple the direct air capture process from secondary carbon emissions and provide additional grid-management options by varying the output of electricity and hydrogen/CO₂. 

DOE Funding: $2,999,681
Non-DOE Funding: $749,943
Total Value: $3,749,624

 

Spiral-Wound Aerogel Adsorbent Polymers for Direct Air CO₂ Capture (SWAAP) – Palo Alto Research Center, Inc. (PARC) (Palo Alto, California), in collaboration with Lawrence Livermore National Laboratory and Xerox Research Centre of Canada, will develop a Spiral-Wound Aerogel Adsorbent Polymer to integrate PARC’s structured adsorbent into a benchtop direct air capture process.

DOE Funding: $2,999,845
Non-DOE Funding: $749,961
Total Value: $3,749,806

 

AOI-2C – Initial Engineering Design Studies for Advanced Carbon Capture Systems at Existing Power Plant Facilities Utilizing Sustainably-Sourced Biomass

Filer City BiCRS Net-Negative Study – CMS Enterprises Company (Jackson, Michigan) intends to team up with ION Clean Energy, Inc. (ION) and Sargent & Lundy LLC, to execute an initial design engineering study. The purpose of this study is to complete the initial design and develop costing to retrofit the Filer Plant in Filer City, Michigan, with the ability to fire 100% sustainably sourced biomass and implement ION’s post-combustion CO₂ capture technology.

DOE Funding: $1,416,224
Non-DOE Funding: $354,056
Total Value: $1,770,280

 

AOI-2E – Initial Engineering Design Studies for Advanced Carbon Capture Systems at Existing Iron and Steel, Cement and Lime, or Pulp and Paper Plants Utilizing Sustainably-Sourced Biomass

Net-Zero Lime Kiln and Carbon Removal Facility – Electricore, Inc. (Valencia, California) plans to execute and complete the initial design of a commercial-scale, advanced carbon capture system that separates CO₂ with at least 95% capture efficiency from process streams at the Carmeuse Kentucky lime plant. The plant will be retrofitted to utilize sustainably sourced biomass alone or in combination with natural gas, and/or coal, with at least 20-year available feedstock supply and remaining asset life.

DOE Funding: $1,500,000
Non-DOE Funding: $375,000
Total Value: $1,875,000

 

AOI-4 CAPTURE STORAGE TECHNOLOGY

Distributed Mafic Rock Resources for CO₂ Mineralization in Arizona – Arizona Board of Regents, University of Arizona (Tucson, Arizona) plans to explore surface mafic rocks distributed across four volcanic fields in Arizona as a permanent and safe CO₂ sink. A Mafic Materials Resource Inventory will be created that combines existing rock physical, chemical, and hydrologic data with new mapping and a sample collection of young scoria (cinder) cones and lava flows.

DOE Funding: $832,008
Non-DOE Funding: $215,637
Total Value: $1,047,645

 

Regional Resource Assessment for CO₂ Storage in New Mexico and Surrounding Areas: Identification, Characterization and Evaluation of in-situ Mineralization Site/Complex – New Mexico Institute of Mining and Technology (Socorro, New Mexico) intends to identify and access the statewide resources for potential CO₂ storage via a mineralization process, including basalt formations and mining wastes (termed as resource rock), and characterize the targeted storage site/complex to provide the insights on its storage capacity evaluation.

DOE Funding: $999,878
Non-DOE Funding: $250,735
Total Value: $1,250,613

 

Resource Assessment for Carbon Dioxide Storage via Accelerated Carbonation Reaction with Recycled Concrete Aggregates – Board of Regents, University of Nebraska, University of Nebraska-Lincoln (Lincoln, Nebraska) intends to explore a significant opportunity to permanently store CO₂ as mineral carbonates and silica by reacting with calcium hydroxide and calcium silicate hydrate in the residual mortar adhered to recycled concrete aggregates for less than 24 hours.

DOE Funding: $805,137
Non-DOE Funding: $201,313
Total Value: $1,006,450

 

Resource Assessment of Geological Formations and Mine Waste for Carbon Dioxide Mineralization in the U.S. Mid-Atlantic – Virginia Polytechnic Institute and State University (Blacksburg, Virginia) plans to provide a thorough resource assessment of natural materials and industrial and mine wastes to be used in both in-situ and ex-situ CO₂ mineralization processes in the Mid-Atlantic Region to store large amounts of CO₂. The focus is to assess the reactivity of mafic and ultramafic formations and crushed mine and industrial wastes with CO₂ and their post-mineralization physical properties.

DOE Funding: $999,428
Non-DOE Funding: $249,850
Total Value: $1,249,278

 

Resource Assessment of Industrial Wastes for CO₂ Mineralization – University of North Dakota (Grand Forks, North Dakota) plans to characterize the chemical and physical attributes of industrial residues—such as cement kiln dust, coal ash, sulfur scrubber residues, biomass processing residues, recycled concrete residues, iron and steel slag, and copper slag—and conduct laboratory-scale tests to determine their potential and practical CO₂ storage capacity. The project will also assess the applications and economic value of the formed products and the overall carbon lifecycle implications.

DOE Funding: $1,000,000
Non-DOE Funding: $250,000
Total Value: $1,250,000

 

Subsurface Carbon Mineralization Resources in Hawaiian Basalt – University of Hawaii (Honolulu, Hawaii) plans to determine whether the submerged flanks of extinct Hawaiian volcanoes can be used to effectively mineralize captured anthropogenic CO₂. The project will assess the CO₂ injection and mineralization potential of northeast Hawaii Island’s subsurface basalt formations.

DOE Funding: $1,000,000
Non-DOE Funding: $250,000
Total Value: $1,250,000

 

Subsurface Mafic and Ultramafic Resource Assessment for Carbon Mineralization in the United States – University of Texas at Austin (Austin, Texas), in collaboration with Columbia University, intends to conduct a resource assessment of mafic and ultramafic bodies in the subsurface of the United States to identify permanent CO₂ storage opportunities. Mafic and ultramafic rocks contain high concentrations of cations that can react with CO₂ to form carbonate minerals and permanently sequester CO₂ in mineral form.

DOE Funding: $992,636
Non-DOE Funding: $280,488
Total Value: $1,273,124