Most large-scale projects for the production of low-emission hydrogen are facing important bottlenecks. Only 4% of projects that have been thus far announced are under construction or have taken a final investment decision. Uncertainty about future demand, the lack of infrastructure available to deliver hydrogen to end users and the lack of clarity in regulatory frameworks and certification schemes are preventing project developers from taking firm decisions on investment.

Transparency on the emissions intensity of hydrogen production can bring much-needed clarity and facilitate investment. Using colours to refer to different production routes, or terms such as “sustainable”, “low-carbon” or “clean” hydrogen, obscures many different levels of potential emissions. This terminology has proved impractical as a basis for contracting decisions, deterring potential investors. By agreeing to use the emissions intensity of hydrogen production in the definition of national regulations about hydrogen, governments can facilitate market and regulatory interoperability. This report aims to assist governments in doing so by assessing the emissions intensity of individual hydrogen production routes, for governments to then decide which level aligns with their own circumstances

The emissions intensity of hydrogen production varies widely depending on the production route. Today, hydrogen production is dominated by unabated fossil fuels; emissions need to decrease significantly to meet climate ambitions. The fuel and technology used, the rate at which CO₂ capture and storage is applied, and the level of upstream and midstream emissions all strongly influence the emissions intensity of hydrogen production. For example, production based on unabated fossil fuels can result in emissions of up to 27 kg CO₂‑eq/kg H₂, depending on the level of upstream and midstream emissions. Conversely, producing hydrogen from biomass with CO₂ capture and storage can result in negative emissions, as a result of removing the captured biogenic carbon from the natural carbon cycle. The average emissions intensity of global hydrogen production in 2021 was in the range of 12-13 kg CO₂‑eq/kg H₂. In the IEA Net Zero by 2050 Scenario, this average fleet emissions intensity reaches 6‑7 kg CO₂‑eq/kg H₂ by 2030 and falls below 1 kg CO₂‑eq/kg H₂ by 2050.

The emissions intensity of hydrogen produced with electrolysis is determined by the emissions from the electricity that is used. Using the methodology developed by the International Partnership for Hydrogen and Fuel Cells in the Economy (IPHE)1, renewable electricity2 generation has no associated emissions, resulting in 0 kg CO₂‑eq/kg H₂. In the case of grid electricity, the emissions intensity varies greatly between peak load and baseload hours, depending on which technology is used to meet additional demand for the electrolysers. To reduce emissions, it is therefore important to ensure that grid-connected electrolysers do not lead to an increase in fossil-based electricity generation.

Carbon capture and storage technologies can reduce direct emissions from fossil-based hydrogen production but measures to mitigate upstream and midstream emissions are needed. Hydrogen production from unabated natural gas results in an emissions intensity in the range of 10-14 kg CO₂‑eq/kg H₂, with upstream and midstream emissions of methane and CO₂ in natural gas production being responsible for 1-5 kg CO₂‑eq/kg H₂. Retrofitting existing assets with capture of CO₂ from the feedstock-related use of natural gas (capture rate around 60%) can bring the emissions intensity down to 5‑8 kg CO₂‑eq/kg H₂. Higher capture rates (above 90%) can be achieved with advanced technologies, reducing emissions intensity to 0.8‑6 kg CO₂‑eq/kg H₂, although no plants using these technologies are in operation yet. At high capture rates, the emissions intensity of hydrogen production is dominated by upstream and midstream emissions, which account for 0.7-5 kg CO₂‑eq/kg H₂, underscoring the importance of cutting methane emissions from natural gas operations.

Governments should define roadmaps to decarbonise hydrogen production, both domestic and imported, in accordance with their national circumstances. This report therefore does not provide a generic acceptable upper threshold for the emissions intensity of hydrogen production. However, governments should take into account factors such as emissions intensity, supply volumes and affordability to inform decision-making to scale up production and use of low-‑emission hydrogen. The higher production cost of low-‑emission hydrogen and the relatively young age of existing unabated fossil fuel-based hydrogen production assets in the chemical sector are barriers to the uptake of low-emission hydrogen. Retrofitting existing production assets with CO₂ capture and storage can be a cost-effective near-term option to partially decarbonise production. In regions with abundant renewable resources, the use of renewable electricity to produce hydrogen is set to be the most cost-effective option, even before 2030.