GovBidAlerts
← All opportunities

Technology Licensing Opportunity: Integrated Electrochemical System for Carbon Capture and Hydrogen Production

Key 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

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.

Other notices in this solicitation

Similar open contracts

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