Methanol is increasingly being promoted as a practical alternative fuel for deep-sea shipping, especially for large containerships operating on long-haul routes. Its appeal lies in relatively easy handling, compatibility with modified internal combustion engines, and visible uptake by major shipping lines. At the same time, there is still limited clarity on whether methanol genuinely delivers meaningful climate benefits once real operational and supply-chain conditions are considered. Much of the existing lifecycle literature relies on generic or best-case electricity assumptions and does not fully reflect how ships actually operate on specific trade lanes.
This research addresses that gap by carrying out a region-specific well-to-wake assessment of methanol-fuelled containership operations on the Asia–Europe corridor. Using a representative Shanghai–Rotterdam route, the study combines three factors that are often analysed separately: location-specific electricity mixes used for methanol production, emissions associated with fuel transport and bunkering along the route, and shipboard operational penalties linked to methanol use, including lower volumetric energy density, increased fuel storage requirements, and efficiency impacts on propulsion systems.
The analysis compares fossil-derived methanol, bio-methanol, and e-methanol pathways using gCO₂e per TEU·km as the functional unit, allowing emissions to be evaluated in terms of actual transport work rather than fuel consumption alone. Both present-day and near-term electricity grid scenarios are considered to capture how regional power systems influence overall lifecycle performance.
Early results indicate that methanol’s sustainability is highly conditional. Fossil-based methanol offers only marginal well-to-wake emissions reductions compared to conventional marine fuels. In contrast, e-methanol can deliver significant reductions, but only when produced using low-carbon electricity and supported by efficient logistics and bunkering networks. When shipboard energy penalties and cargo capacity impacts are included, the net benefits are further reduced if upstream conditions are not favourable.
Rather than treating methanol as an inherently sustainable solution, this study frames it as a transition fuel whose climate value depends strongly on where and how it is produced and deployed. By anchoring lifecycle emissions to a real trade lane and operational constraints, the paper aims to contribute a more realistic basis for fuel selection, infrastructure planning, and policy development in maritime decarbonisation.