Abstract
Hydrogen mobility is one option for reducing local emissions, avoiding greenhouse gas (GHG) emissions, and moving away from a mainly oil-based transport system towards a diversification of energy sources. As hydrogen production can be based on a broad variety of technologies already existing or under development, a comprehensive assessment of the different supply chains is necessary regarding not only costs but also diverse environmental impacts. Therefore, in this paper, a broad variety of hydrogen production technologies using different energy sources, renewable and fossil, are exemplarily assessed with the help of a Life Cycle Assessment and a cost assessment for Germany. As environmental impacts, along with the impact category Climate change, five more advanced impact categories are assessed. The results show that from an environmental point of view, PEM and alkaline electrolysis are characterized by the lowest results in five out of six impact categories. Supply chains using fossil fuels, in contrast, have the lowest supply costs; this is true, e.g., for steam methane reforming. Solar powered hydrogen production shows low impacts during hydrogen production but high impacts for transport and distribution to Germany. There is no single supply chain that is the most promising for every aspect assessed here. Either costs have to be lowered further or supply chains with selected environmental impacts have to be modified.
Highlights
For several years hydrogen has been discussed widely for mobility applications in order to minimize local emissions, reduce overall greenhouse gas (GHG) emissions and decrease dependency on foreign fossil fuel resources
Fuel cell electric vehicles (FCEV) from different manufacturers are already available on the market [1]
Liquid organic hydrogen carriers (LOHCs) for transport are compared with liquid hydrogen transport
Summary
Hydrogen has been discussed widely for mobility applications in order to minimize local emissions, reduce overall greenhouse gas (GHG) emissions and decrease dependency on foreign fossil fuel resources. For the production and transport of hydrogen, a broad variety of technologies either already exist or are currently under development and/or investigation In this context, several recent articles discuss technical aspects of hydrogen production [2,3,4,5,6]. Other authors focus on distributing hydrogen, in particular the hydrogen refueling station (HRS) (e.g., Burkhardt, et al [16]) They investigated different environmental impact categories but only for hydrogen production from wind energy directly at the hydrogen refueling station (HRS). The production of hydrogen is included, and transport and distribution in Germany (i.e., the whole supply chain for mobility purposes is covered) In this way, a comprehensive picture can be drawn and the positive and negative aspects of current and future technologies for hydrogen supply can be discussed
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