Achieving deep decarbonization in hard-to-abate sectors requires scalable low-carbon fuels derived from biogenic or air-captured CO 2 . E-Methanol is a promising option, but its deployment depends on robust CO 2 value chains that integrate industrial emissions, conditioning, multi-modal transport and reliable supply of power. Despite progress in carbon capture research, integrated assessments combining real emitters, CO 2 logistics, storage design, downtime-driven oversizing and transport fleet operations remain unavailable, limiting accurate levelized cost prediction of e-fuel value chain. The study proposed a unified framework to evaluate the techno-economic feasibility of the overall CO 2 -to-e-methanol chain, integrating capture, liquefaction, storage, different transport possibilities and final synthesis. Results show that CO 2 availability strongly determines feasible plant size, while transport mode significantly shapes logistics cost. E-methanol synthesis is the largest contributor, with the Portuguese cement scenario yielding 1111.3 €/t. Across the analysed scenarios, maritime transport usually delivers 51–60% lower cost than road transport. The framework supports rigorous planning of CCU-enabled e-fuel synthesis.
Vendrell-Granero et al. (Sat,) studied this question.
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