Industries including energy, steel and chemicals are looking to develop large-scale hydrogen applications to help reduce carbon emissions and avert global warming.
Although hydrogen is the most abundant element in the universe, it’s very scarce as a gas, and so far most methods of producing gas at scale release large amounts of carbon dioxide.
Hydrogen is colourless, but each form of it has been categorised by a colour that reflects its carbon footprint: The ultimate is green hydrogen, extracted using power from renewable energy such as wind or solar.
Here are details about green, grey, blue and turquoise hydrogen:
- Green hydrogen
Derived from renewable sources which could include offshore wind, powering floating electrolysis plants. Green hydrogen can be stored, piped, or carried by tankers to consumers, for example to serve hydrogen filling stations. So far it has mostly been produced for experimental projects.
- Grey hydrogen
Grey hydrogen is extracted from natural gas using steam-methane reforming, currently the standard industry process.
- Blue hydrogen
Blue hydrogen is produced in the same way as grey hydrogen but with CO2 emissions captured for underground or subsea storage. It’s often presented as a transitional approach until green hydrogen output can scale up.
- Turquoise hydrogen
Also called low-carbon hydrogen, and so far very small scale, this is hydrogen generated from natural gas but using pyrolysis – the gas is passed through molten metal, producing solid carbon as a byproduct with useful applications.