The process of generating hydrogen as an energy carrier, particularly through electrolysis using renewable electricity, to create zero-emission fuel.
Key Components:
- Electrolysis: Splitting water into hydrogen and oxygen using electricity.
- Hydrogen Storage: Compressing or liquefying hydrogen for transport and use.
- Fuel Cells: Converting hydrogen into electricity through an electrochemical process.
Use Cases/Industries:
- Transportation: Powering fuel cell electric vehicles (FCEVs) such as buses, trucks, and ships.
- Industrial Applications: Replacing fossil fuels in steel production, ammonia manufacturing, and refining.
- Energy Storage: Acting as a long-term energy carrier for excess renewable power.
Advantages:
- Zero Carbon Emissions: Green hydrogen produces only water vapor when used in fuel cells.
- Versatile Energy Carrier: Can be stored and transported for multiple applications.
- Supports Decarbonization: Enables deep emission reductions in hard-to-electrify sectors.
Challenges:
- High Production Costs: Electrolysis requires significant amounts of electricity, making green hydrogen costly.
- Infrastructure Limitations: Requires new storage, transport, and distribution networks.
- Energy Losses: Efficiency losses occur during hydrogen production, storage, and conversion.
Related Terms:
Fuel Cell Technology, Hydrogen Storage, Power-to-Gas
Example:
A green hydrogen plant in Germany produces renewable hydrogen using wind power, supplying fuel for zero-emission public transportation systems.
Visited 1 times, 1 visit(s) today
Synonyms:
Green Hydrogen, Hydrogen Energy, Renewable Hydrogen Fuel
