Effect of hydrogen leakage on the life cycle climate impacts of hydrogen supply chains
Esther Goita, Emily Beagle, Ansh N. Nasta, Derek L. Wissmiller, Arvind Ravikumar, Michael E. Webber
Abstract
Hydrogen is of interest for decarbonizing hard-to-abate sectors because it does not produce carbon dioxide when combusted. However, hydrogen has indirect warming effects. Here we conducted a life cycle assessment of electrolysis and steam methane reforming to assess their emissions while considering hydrogen’s indirect warming effects. We find that the primary factors influencing life cycle climate impacts are the production method and related feedstock emissions rather than the hydrogen leakage and indirect warming potential. A comparison between fossil fuel-based and hydrogen-based steel production and heavy-duty transportation showed a reduction in emissions of 800 to more than 1400 kg carbon dioxide equivalent per tonne of steel and 0.1 to 0.17 kg carbon dioxide equivalent per tonne-km of cargo. While any hydrogen production pathway reduces greenhouse gas emissions for steel, this is not the case for heavy-duty transportation. Therefore, we recommend a sector-specific approach in prioritizing application areas for hydrogen. Production method (such as electrolysis and steam methane reforming) and related feedstock emissions are the key factors which influence hydrogen emissions from supply chains, according to life cycle assessment of hydrogen production pathways.