LONDON, UK – 03 September 2025:Independent research and energy intelligence firmRystad Energyhas published the results of a landmark study on the greenhouse gas (GHG) emissions from the LNG bunker supply chain, commissioned bySEA-LNG. This is the most accurate and up-to-date certified data on LNG as a marine fuel designed to help guide the International Maritime Organization’s (IMO’s) Net-Zero Framework and future fuel policy.
The implications for policy makers developing regulations to decarbonise shipping resulting from this study are:
The study analyses the emissions originating from the five key fuel lifecycle stages: upstream, transportation & processing, liquefaction, shipping, and distribution & bunkering operations. It was conducted in line with the IMO WtT lifecycle analysis guidelines, the Intergovernmental Panel on Climate Change’s (IPCC) AR5 GHG definitions, and is based on asset-specific 2024 data.
The study finds that the global well-to-tank emissions intensity for LNG bunkering fuel in 2024 is13.9g /MJ (LHV).Carbon dioxide dominates global WtT emissions, responsible for 84% of emissions. Carbon dioxide emissions were most prevalent in the liquefaction stage, responsible for 99% of the stage’s 5.9 g /MJ.
Methane emissions were responsible for 16% of total WtT emissions, equivalent to 2.2 g /MJ. They were most prevalent in upstream gas production lifecycle stage, responsible for 38% of total emissions from that stage.
On a global basis, upstream gas production and liquefaction were responsible for the majority of bunker supply chain emissions at 30% and 43% respectively. Consequently, these two stages should be the focus for most future decarbonisation efforts. From the upstream perspective, methane mitigation is best poised to deliver the greatest emissions reduction benefits. Improvements in liquefaction emissions have been observed over recent years, tied to greater utilisation of more efficient technologies. It is likely this trend will continue when coupled with key electrification projects using renewable energy such as hydro and solar power.
With around 95% of vessels still powered by oil-based marine fuels, LNG represents the leading alternative and already accounts for nearly 20% of the vessel orderbook. As the industry transitions toward net-zero and prepares for a rapidly expanding fleet of LNG-fuelled vessels, understanding the real-world lifecycle emissions of LNG is critical to shaping effective regulation and guiding future investment decisions.
Results also show wide variation between regions and cargoes, reflecting differences in gas sources, liquefaction technologies, and shipping distances. In some cases, emissions intensities differed by as much as6.6 g /MJ, highlighting that a single global average does not capture the full picture and risks leading to poorly informed regulatory choices.
Patrick King, Vice President Emissions Research, Rystad Energy commented:“Our analysis is based on asset-level data that ties specific gas fields to liquefaction facilities. This approach, supported by satellite-detected methane plume data and reported asset information, gives a more accurate picture of the LNG actually used for bunkering, rather than relying on outdated or overly broad averages.”
Steve Esau (pictured above), Chief Operating Officer of SEA-LNG, said: “Policymakers must create regulations that reflect the true carbon intensity of marine fuels, rewarding reductions across the supply chain.
Marine regulators should incentivise participants in the LNG bunker supply chain to continue to reduce GHG emissions.”
Peter Keller, Chairman of SEA-LNG, concluded: “This landmark report sets the high standards the IMO should demand on such a key topic as alternative fuel emissions and performance within the Net-Zero Framework. Decisions must be based on real and recent data or risk undermining the significant progress already made along the practical and realistic LNG pathway to decarbonisation.”
Download the full Rystad Energy LNG well-to-tank emissions analysishere.
