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Slow-Steaming Climate Strategies For Abatement Efforts In Maritime Shipping

dc.contributor.advisorNolan, James
dc.contributor.advisorLloyd-smith, Patrick
dc.contributor.committeeMemberLiebenehm, Sabine
dc.contributor.committeeMemberSantiago, Leonardo
dc.contributor.committeeMemberHesseln, Hayley
dc.creatorLassoued, feryel
dc.date.accessioned2023-01-13T04:33:09Z
dc.date.available2023-01-13T04:33:09Z
dc.date.copyright2022
dc.date.created2022-12
dc.date.issued2023-01-12
dc.date.submittedDecember 2022
dc.date.updated2023-01-13T04:33:09Z
dc.description.abstractMaritime shipping is a major contributor to climate change – accounting for 2.89\% of Global CO2 emissions in 2018. Given the “light hand” of regulatory institutions governing commercial activities on the high seas, attempts to reduce the emissions of ocean-going ships have not been successful. In this thesis, the impacts of emission policies and incentives for cooperation in the international maritime shipping industry are examined. The International Maritime Organization (IMO) – the regulator – GHG Strategy puts forth both “speed optimisation” and “speed reduction” as candidate measures for short-term emission abatement. These terms are poorly defined, however, leading to different interpretations. Slow steaming, or deliberately reducing ships’ speed, allows firms to decrease fuel consumption and therefore, emissions. Grounded in this rationale, a flexible numerical simulation model is developed for a market comprised of heterogeneous shipping companies to investigate maritime shipping abatement dynamics under various slow steaming policies. First, we project firms' business-as-usual (BAU) operations and then analyse both policies: Speed reduction – relative to BAU levels and Speed optimisation – as firms' climate strategy response to meet various emission caps. The simulation results suggest that firms already slow-steam when economically optimal (i.e. by evaluating the trade-off between fuel savings and time-dependent operating costs). Even more so, they show that speed optimization -as an abatement strategy- provides firms with the flexibility to derive their optimal Slow-Steaming rates to sustain a regulator's environmental policy. In contrast, we find that Slow-Steaming - as a command and control policy- shifts regulatory focus and is difficult to enforce in international waters. The simulation model was also used to analyze a two-stage, cooperative game of coalition formation with heterogeneous firms and individual abatement strategies. In the first stage, firms decide whether to join a coalition or not (membership decision). Coalition signatories adopt the operational slow-steaming climate strategy over the planning horizon and choose the abatement levels that maximise the sum of their payoffs under a joint emission budget constraint. On the other hand, non-signatories to the coalition (singletons) optimise their own abatement level by maximizing individual payoffs, subject to their own individual caps. Our results indicate that cooperation allows firms with heterogeneous abatement cost curves to pool resources and properly allocate speed reduction endeavours to sustain an emission target. Thus, industry-level climate strategies withhold the potential to improve environmental sustainability through cooperation for ocean shipping.
dc.format.mimetypeapplication/pdf
dc.identifier.urihttps://hdl.handle.net/10388/14410
dc.language.isoen
dc.subjectMaritime transportation, Liner service, Slow-Steaming, Speed reduction, Speed optimization, Genetic Algorithms, GHG Emissions, Emission caps"
dc.titleSlow-Steaming Climate Strategies For Abatement Efforts In Maritime Shipping
dc.typeThesis
dc.type.materialtext
thesis.degree.departmentAgricultural and Resource Economics
thesis.degree.disciplineAgricultural Economics
thesis.degree.grantorUniversity of Saskatchewan
thesis.degree.levelMasters
thesis.degree.nameMaster of Science (M.Sc.)

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