Pollution Tradeoffs for Conventional and Natural Gas-Based Marine Fuels

James J Winebrake,Daniel Yuska,James J Corbett,Fatima Umar

doi:10.3390/su11082235

Abstract

This paper presents a life-cycle emissions analysis of conventional and natural gas-based marine transportation in the United States. We apply a total fuel cycle—or “well-to-propeller”—analysis that evaluates emissions along the fuel production and delivery pathway, including feedstock extraction, processing, distribution, and use. We compare emissions profiles for methanol, liquefied natural gas, and low sulfur marine fuel in our analysis, with a focus on exploring tradeoffs across the following pollutants: greenhouse gases, particulate matter, sulfur oxides, and nitrogen oxides. For our greenhouse gas analysis, we apply global warming potentials that consider both near-term (20-year) and long-term (100-year) climate forcing impacts. We also conduct uncertainty analysis to evaluate the impacts of methane leakage within the natural gas recovery, processing, and distribution stages of its fuel cycle. Our results indicate that natural-gas based marine fuels can provide significant local environmental benefits compared to distillate fuel; however, these benefits come with a near-term—and possibly long-term—global warming penalty, unless such natural gas-based fuels are derived from renewable feedstock, such as biomass. These results point to the importance of controlling for methane leaks along the natural gas production process and the important role that renewable natural gas can play in the shipping sector. Decision-makers can use these results to inform decisions related to increasing the use of alternative fuels in short sea and coast-wise marine transportation systems.

Highlights

Marine transportation is an important source of regional air pollution in many parts of the world and represents 15% and 13% of the global emissions burden for nitrogen oxides (NOx) and sulfur oxides (SOx), respectively [1]
Due to human health and other ecological risks, some nations have imposed emissions control areas (ECAs) that restrict emissions from vessels operating within defined coastal boundaries, and the International Maritime Organization (IMO) has adopted new fuel standards aimed at significantly reducing the sulfur content in marine fuels by 2020 [2,3,4,5,6]
Combined with new emphasis on near-term climate forcing impacts, we show these upstream CH4 emissions to have considerable impact on the overall climate change impacts of switching from marine distillate oil (MDO) to NG-based fuels, except in cases where the natural gas is derived from renewable sources, such as biomass

Summary

Introduction

Marine transportation is an important source of regional air pollution in many parts of the world and represents 15% and 13% of the global emissions burden for nitrogen oxides (NOx) and sulfur oxides (SOx), respectively [1] These pollutants pose significant health risks to exposed populations and are responsible for hundreds of thousands of premature deaths and millions of respiratory illnesses worldwide annually [2,3,4]. The shipping sector is considering several approaches to meet ECA and IMO regulations, including the installation of on-board pollution control equipment and the switch from petroleum-based fuels to cleaner fuels In this latter category, two fuels that have gained attention due to their fuel properties are liquefied natural gas (LNG) and methanol (MeOH) [7,8,9,10]. The choice that ship operators make will depend on costs, fuel availability, refueling infrastructure, safety, and operational factors, among others [8]

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Results

Conclusion