Sentences with phrase «advanced hydrogen production»

Canadian Nuclear Laboratories is accelerating the transition to a hydrogen economy with advanced hydrogen production and energy storage technologies.

Learn more about how CNL is accelerating the transition to a hydrogen economy through advanced hydrogen production and energy storage technologies.

Wood also is a principal investigator in the Department of Energy Office of Energy Efficiency and Renewable Energy's (EERE) HydroGEN Advanced Water Splitting Materials Consortium, an Energy Materials Network node focused on hydrogen production froHydroGEN Advanced Water Splitting Materials Consortium, an Energy Materials Network node focused on hydrogen production frohydrogen production from water.

Advanced materials are essential in improving the overall system efficiency at high hydrogen production rates, reducing capital cost, and efficiently using renewable and industrial waste heats.

Future technologies that need R&D: high - efficiency photovoltaics (say, 50 % conversion)(as well as lowering the cost of PV), energy storage systems for intermittent sources like solar and wind (hydrogen storage, other methods), advances in biofuel technology (for example, hydrogen production from algae, cellulosic ethanol, etc..)

The HydroGEN program encompasses advanced electrolytic, photoelectrochemical, and solar thermochemical hydrogen production prHydroGEN program encompasses advanced electrolytic, photoelectrochemical, and solar thermochemical hydrogen production prhydrogen production processes.

He also is principal investigator for the DOE EERE HydroGEN Advanced Water Splitting Materials Consortium, an energy materials network focused on hydrogen production froHydroGEN Advanced Water Splitting Materials Consortium, an energy materials network focused on hydrogen production frohydrogen production from water.

This capability involves the exposure of advanced production or storage alloys to hydrogen atmospheres along with extended analysis capabilities on physical and microstructural evolution along with mechanical performance.

This capability can screen advanced alloys for harsh environments associated with hydrogen production, both quantifying material performance and uncovering fundamental microstructural mechanisms.

The HydroGEN Advanced Water Splitting Materials Consortium (HydroGEN) will utilize the expertise and capabilities of the national laboratories to accelerate the development of commercially viable pathways for hydrogen production from renewable energy HydroGEN Advanced Water Splitting Materials Consortium (HydroGEN) will utilize the expertise and capabilities of the national laboratories to accelerate the development of commercially viable pathways for hydrogen production from renewable energy HydroGEN) will utilize the expertise and capabilities of the national laboratories to accelerate the development of commercially viable pathways for hydrogen production from renewable energy hydrogen production from renewable energy sources.

Multiple technologies will be explored within the HydroGEN program including advanced electrolysis, photoelectrochemical processes, and solar thermochemical hydrogen proHydroGEN program including advanced electrolysis, photoelectrochemical processes, and solar thermochemical hydrogen prohydrogen production.

DOE's $ 10M Advanced Water Splitting Materials Consortium accelerating development of green hydrogen production

Researchers at the Energy Department's National Renewable Energy Laboratory (NREL) have made advances toward affordable photoelectrochemical (PEC) production of hydrogen.

Directs the Secretary to conduct programs in partnership with the private sector that address: (1) hydrogen production from diverse energy sources; (2) use of hydrogen for commercial, industrial, and residential electric power generation; (3) safe delivery of hydrogen or hydrogen - carrier fuels, (4) advanced vehicle technologies; (5) storage of hydrogen or hydrogen - carrier fuels; (6) development of safe, durable, affordable, and efficient fuel cells; and (7) the ability of domestic automobile manufacturers to manufacture commercially available competitive hybrid vehicle technologies in the United States.

Most advanced routes for solar production of hydrogen, syngas, and liquid fuels have been demonstrated at pilot scale.

Specific areas of interest include, but are not limited to: biological, thermochemical, or thermocatalytic routes for the conversion of lignocellulosic biomass to advanced biofuels beyond cellulosic ethanol; microbial fuel cells for direct production of electricity from renewable carbon sources; hydrogen production from autotrophic or heterotrophic microorganisms; hydrocarbons and lipids from phototrophic or heterotrophic microorganisms.