Abstract
Negative emission technologies have recently received increasing attention due to climate change and global warming. One among them is bioenergy with carbon capture and storage (BECCS), but the capture process is very energy intensive. Here, a novel pathway is introduced, based on second-generation biofuels followed by carbon circulation in an indefinitely closed chain, effectively resulting in a sink. Instead of using an energy-intensive conventional CCS process, the application of an on-board solid oxide fuel cell (SOFC) running on biofuels in an electric vehicle (FCEV) could result in negative emissions by capturing a concentrated stream of CO2, which is readily stored in a second tank. A CO2 recovery system at the fuel station then takes the CO2 from the tank to be transported to storage locations or to be used for local applications such as CO2-based concrete curing and synthesis of e-fuels. Incorporating CO2 utilization technologies into the FCEVs-SOFC system can close the carbon loop, achieving carbon neutrality through feeding the CO2 in a reverse-logistic to a methanol plant. The methanol produced is also used in SOFCs, leading to an infinite repetition of this carbon cycle till a saturation stage is reached. It is determined this pathway will reach typical Cradle-to-Grave negative emissions of 0.515 ton CO2 per vehicle, and total negative CO2 emission of 138 Mt for all passenger cars in the EU is potentially achievable. All steps comprise known technologies with medium to high technology readiness level (TRL) levels, so principally this system can readily be applied in the mid-term.
Highlights
There is a concern that global CO2 emission reductions will not meet targets
In the solid oxide fuel cell (SOFC) unit, the electrochemical fuel oxidation involves the automatic separation of nitrogen from oxygen, and the anode output is passed through an oxyfuel combustion system in which the unused fuel is burned with pure oxygen, thereby producing a CO2-enriched gas
Assuming there is a lag time of 1 year between the CO2 from a car being captured and being provided to a car again as methanol, maximum negative emission of 0.515 ton CO2 is achievable for each SOFC-equipped car that uses bioethanol with CCU
Summary
There is a concern that global CO2 emission reductions will not meet targets. Measures in the field of energy efficiency, bio-based fuels, material recycling, and decarbonization may not be sufficient to reach the 1.5–2 ◦C targets set for global warming. One of the important negative emission pathways is bioenergy carbon capture and storage (BECCS) This route comprises power generation combusting biomass into energy or biomass digestion into biogas. In the SOFC unit, the electrochemical fuel oxidation involves the automatic separation of nitrogen from oxygen, and the anode output is passed through an oxyfuel combustion system in which the unused fuel (since fuel utilization is not 100% in SOFCs) is burned with pure oxygen (with the oxygen taken from a separate tank, and possibly coming from electrolysers), thereby producing a CO2-enriched gas In this way, very high-purity CO2 can be separated by condensing water vapor (Thattai et al, 2017; Slater et al, 2019)
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