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GCMD’s life cycle study quantifies net GHG emissions savings for pathways with Onboard Carbon Capture and Storage (OCCS)

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SINGAPORE : A comprehensive life cycle assessment (LCA) conducted by the Global Centre for Maritime Decarbonisation (GCMD) quantifies OCCS’s potential to provide GHG emissions savings.

The study, named COLOSSUS (Carbon capture, offloading, onshore storage, utilisation and permanent storage), provides an in-depth analysis of GHG emissions and costs associated with OCCS across the entire carbon value chain, accounting for emissions from fuel production, transport and use, to CO2 capture onboard the vessel and its final disposition.

LCAs facilitate an equivalent comparison of different decarbonisation measures; this comparison can help shipowners make informed decisions on solutions adoption based on their net abatement impact across the entire carbon value chain. This holistic quantification of emissions ensures that OCCS adoption does not lead to inadvertent increases in emissions in adjacent sectors because of decisions made downstream.

While LCAs are available for onshore carbon capture technologies in themselves, assessments of the overall GHG emissions from deploying these solutions onboard vessels across the associated value chains are limited. A full assessment would require the inclusion of the well-totank (WtT) emissions of the fuel, onboard tank-to-wake (TtW) emissions, including those associated with OCCS operations, the subsequent emissions from transporting captured CO2, and those associated with permanent storage or its utilisation.

What this study considers

The study used a WtW GHG emissions of 93.3 gCO2eq/MJ for Heavy Fuel Oil (HFO) as a baseline for comparison against other scenarios. This study explored five OCCS technologies, with six marine fuel options, and three post-capture scenarios. Among OCCS technologies, the study examined different post-capture scenarios with conventional monoethanolamine (MEA)- based OCCS, with it being the most mature of the OCCS technologies in the industry. Based on the practical limitations of storing large quantities of liquid CO2 onboard vessels, the study further assumed a 40% gross carbon capture for all scenarios explored, consistent with industry recommendations.

Key findings

Notably, the deployment of conventional MEA-based OCCS can result in a WtW GHG emissions savings of 29% for an HFO-fuelled ship.

Replacing HFO with biofuels presents a promising strategy for maximising GHG emissions savings. The WtW emissions savings for a vessel deploying MEA-based OCCS range from 69% to 121% when using bio-LNG and biodiesel from used cooking oil, respectively.

Among the post-capture scenarios evaluated, fixing the captured CO2 in concrete is most effective. This approach can increase GHG emissions savings from 29% to 60% across the carbon value chain by partially displacing the need for carbon-intensive cement in applications ashore.

Post-capture transport and permanent storage of CO2 add minimal emissions, approximately 1% to the WtW emissions of a vessel deploying MEA-based OCCS when the captured CO2 is transported 1,000 km. Captured CO2 can also be used to produce e-methanol with renewable electricity, allowing the vessel that consumes this e-methanol to claim a 17% GHG emissions savings.

The cost of avoided carbon for OCCS with permanent storage is between USD 269-405/tCO2 for a 40% gross capture on an MR tanker, considering a full-scale, Nth-of-a-kind installation of an OCCS system with full heat recovery.

Viability of OCCS to help shipowners reduce GHG emissions

While the recently articulated GHG Fuel Intensity (GFI) framework does not explicitly specify how emissions reduction from OCCS is taken into consideration, the study offers a structured basis for assessing the solution’s potential in helping shipowners and operators manage their emissions portfolio.

By calculating the abatement from OCCS based on the amount of CO₂ it removes per unit of energy (in gCO₂eq/MJ) on a WtW approach, an “equivalent” GFI can be derived. Extending this concept, the study shows an HFO-fuelled ship adopting MEA-based OCCS at 40% gross capture can, on a WtW basis, maintain an equivalent GFI below the direct compliance target until 2032. Similarly, LNG-fuelled ships equipped with the same OCCS can maintain an equivalent GFI below the direct compliance target until 2035. Further, when fossil fuels are completely replaced by their bio-counterparts, OCCS can lower the GFI enough for the ship to be compliant with the more stringent 2040 targets.

Professor Lynn Loo, CEO, GCMD said: “As we face an increasing array of decarbonisation solutions spanning different industries and value chains, coupled with the challenges of quantifying and elucidating carbon flows from source to sink including its re-use, there is a pressing need for a comparable means to understand their net abatement impact. We hope this LCA study for OCCS provides a foundation for the comprehensive understanding needed to shape robust regulatory frameworks surrounding OCCS, and supports decision makers in making informed, value chain-based decisions.”

To access the full study findings, please download the report here.

About the Global Centre for Maritime Decarbonisation

The Global Centre for Maritime Decarbonisation (GCMD) was established as a non-profit organisation on 1 August 2021 with a mission to support the decarbonisation of the maritime industry by shaping standards, deploying solutions, financing projects, and fostering collaboration across sectors.

Founded by six industry partners namely BHP, BW Group, Eastern Pacific Shipping, Foundation Det Norske Veritas, Ocean Network Express and Seatrium, GCMD also receives funding from the Maritime and Port Authority of Singapore (MPA) for qualifying research and development programmes and projects. Since its founding, bp, Hanwha Ocean, Hapag-Lloyd and NYK Line have joined as Strategic partners. To date, over 130 centre- and project-level partners have joined GCMD, contributing funds, expertise and in kind support to accelerate the deployment of scalable low-carbon technologies and lowering adoption barriers.

Since its establishment, GCMD has launched four key initiatives to close technical and operational gaps in: deploying ammonia as a marine fuel, developing an assurance framework for drop-in green fuels, unlocking the carbon value chain through onboard carbon capture and articulating the value chain of captured carbon dioxide as well as closing the data-financing gap to widen the adoption of energy efficiency technologies.

GCMD is strategically located in Singapore, the world’s largest bunkering hub and busiest transshipment port.

For more information, go to www.gcformd.org.

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