Special NoticeActiveBA-1324
Technology Licensing Opportunity: Integrated Electrochemical System for Carbon Capture and Hydrogen Production
ENERGY, DEPARTMENT OF / ENERGY, DEPARTMENT OF / BATTELLE ENERGY ALLIANCE–DOE CNTRKey dates?
- Posted?
- Mar 4, 2026
- Response deadline?
- May 1, 2025, 6:00 AM UTC
- Archive date?
- —
- Archive type?
- auto15
Classification?
- Notice type?
- Special Notice
- Base type?
- Special Notice
- Set-aside?
- —
- Set-aside code?
- —
- PSC?
- AJ13
NAICS?
Issuing office?
- Department?
- ENERGY, DEPARTMENT OF
- Sub-tier?
- ENERGY, DEPARTMENT OF
- Office?
- BATTELLE ENERGY ALLIANCE–DOE CNTR
- Office code?
- —
- Organization type?
- OFFICE
- Office address?
- Idaho Falls, ID, 83415, USA
Place of performance?
- Street?
- —
- Street 2?
- —
- City?
- Idaho Falls
- State?
- ID
- Zip?
- 83401
- Country?
- USA
Contacts?
- Javier Martinezprimary
Description?
Integrated Electrochemical System for Carbon Capture and Hydrogen Production A Modular, Energy-Efficient Solution for Reducing Atmospheric CO? The Challenge Current carbon capture technologies face significant hurdles in addressing both distributed CO? emissions and direct air capture (DAC). Current solutions are: Energy Intensive: Traditional methods rely on chemical solvents or solid adsorbents that demand high heat, steam, and electricity for regeneration. Infrastructure Heavy: Large absorption and desorption towers increase capital costs and system complexity. Inefficient DAC for Low CO? Concentrations: Capturing CO? from ambient air (400 ppm) remains technologically and economically challenging. These limitations impede scalability and economic viability, especially as global CO? emissions from distributed sources like transport remain a critical challenge. How It Works The proposed technology integrates a Carbonate-Composite Membrane Reactor (CCMR) with a Protonic Ceramic Electrolyzer (PCE) to enable efficient carbon capture, hydrogen production, and energy generation: Carbonate-Composite Membrane Reactor (CCMR): Captures CO? directly from ambient air while generating electricity and steam. Protonic Ceramic Electrolyzer (PCE): Produces renewable hydrogen using the steam and electricity generated by the CCMR. Thermal Balance: Couples the exothermic CCMR and endothermic PCE to create a thermally uniform and energy-efficient system. Closed Water Loop: Water produced in the CCMR is used for hydrogen production in the PCE, ensuring net-zero water consumption. This hybrid approach minimizes energy loss, reduces auxiliary power demand, and eliminates the need for traditional solvent regeneration processes. Key Advantages Energy Efficiency: Generates electricity and reuses heat within the system, lowering overall energy requirements. Net-Zero Water Consumption: Closed-loop operation ensures sustainable water usage. Scalability: Modular design supports deployment as distributed DAC units or centralized stations. Versatility: Operates at intermediate temperatures (~600°C), enabling integration with waste heat sources and a range of applications. Simplified Operation: Eliminates adsorption/desorption regeneration, reducing system complexity and costs. Sustainable Hydrogen Production: Uses renewable H? to drive CO? capture, achieving net-zero or negative emissions. Market Applications Carbon Management: Direct air capture for mitigating global CO? emissions. Industrial CO? Use: Captured CO? can be used for enhanced oil recovery, synthetic fuel production, and food/beverage carbonation. Distributed or Mobile Carbon Capture: Ideal for addressing emissions from transportation and other distributed sources. Point Source Applications: Captures CO? from concentrated sources, such as power plants or industrial facilities.
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Metadata?
- Notice ID?
- 46f440fea8504a3c9190bd1677d4bc61
- Full path?
- ENERGY, DEPARTMENT OF.ENERGY, DEPARTMENT OF.BATTELLE ENERGY ALLIANCE–DOE CNTR
- Office code?
- —
- Ingested?
- Jun 12, 2026
- Updated?
- Jun 15, 2026