Workshop Article
Title: A Decision Support Tool for Optimizing Fuel Deployment and Emissions Reduction: Advanced Modeling Approach to Sustainable U.S. Maritime Transport
Publication Date:
Pages:
13
Publisher:
One Petro
Fuels Group:
Fuel Blends Mentioned?
Yes
Feedstocks Group:
Pathways Group:
Vessel Segment:
Language:
English
Document Access
Website:
Citation
APA
Mesineni, S. (2025). A Decision Support Tool for Optimizing Fuel Deployment and Emissions Reduction: Advanced Modeling Approach to Sustainable U.S. Maritime Transporthttps://doi.org/10.5957/tos-2025-018
BibTex
@conference{Mesineni-2025-3912,
author = {Mesineni, S},
title = {A Decision Support Tool for Optimizing Fuel Deployment and Emissions Reduction: Advanced Modeling Approach to Sustainable U.S. Maritime Transport},
year = {2025},
month = {jan},
pages = {13},
publisher = {One Petro},
doi = {10.5957/tos-2025-018},
url = {https://ww2.arb.ca.gov/sites/default/files/barcu/regact/2021/chc2021/appe.pdf},
keywords = {Unspecified Feedstock, Marine Diesel Oil (MDO), Marine Gas Oil (MGO), Methane (Natural Gas), Ammonia, Heavy Fuel Oil (HFO), Unspecified Pathway, Lifecycle Assessment (LCA) and Air Emissions, Ocean-going Vessels},
}
author = {Mesineni, S},
title = {A Decision Support Tool for Optimizing Fuel Deployment and Emissions Reduction: Advanced Modeling Approach to Sustainable U.S. Maritime Transport},
year = {2025},
month = {jan},
pages = {13},
publisher = {One Petro},
doi = {10.5957/tos-2025-018},
url = {https://ww2.arb.ca.gov/sites/default/files/barcu/regact/2021/chc2021/appe.pdf},
keywords = {Unspecified Feedstock, Marine Diesel Oil (MDO), Marine Gas Oil (MGO), Methane (Natural Gas), Ammonia, Heavy Fuel Oil (HFO), Unspecified Pathway, Lifecycle Assessment (LCA) and Air Emissions, Ocean-going Vessels},
}
RIS
TY - CONF
TI - A Decision Support Tool for Optimizing Fuel Deployment and Emissions Reduction: Advanced Modeling Approach to Sustainable U.S. Maritime Transport
AU - Mesineni, S
AB - The shipping industry, particularly containerized cargo transport, plays a vital role in global trade, but it is also a significant contributor to greenhouse gas (GHG) emissions. With increasing pressure to reduce carbon footprints and achieve sustainability targets, the U.S. maritime sector is seeking innovative solutions to lower its environmental impact. Optimizing fuel usage, improving operational efficiencies, and adopting alternative fuels are essential strategies to decarbonize maritime transport. However, these complex challenges require sophisticated tools for simulating and analyzing different fuel and routing strategies. The US Department of Energy, Advanced Research Projects Agency - Energy funded a project to focuses on developing an advanced decision-support tool to optimize fuel deployment and intermodal freight routing for domestic container shipping in the U.S., aiming to reduce GHG emissions and improve operational efficiency.This project aims to develop an advanced decision-support tool that leverages modeling and simulation to optimize fuel deployment and intermodal freight route planning for domestic container shipping across U.S. maritime corridors. The tool's central goal is to simulate and assess vessel operations, considering both environmental impact and operational efficiency, with a focus on reducing greenhouse gas (GHG) emissions through intelligent fuel selection and optimized routing strategies. The project will integrate traditional oil-based vessel technologies with alternative/Low emission fuels, specifically methanol and ammonia/hydrogen, to evaluate these technologies' potential for decarbonizing the maritime sector.The modeling scope encompasses several critical aspects of container shipping operations: it will simulate container and containership movements across key U.S. maritime routes, including both open sea and inland waterways (e.g., from Los Angeles to Seattle). The simulation will track vessel movements in real-time, incorporating key operational events such as departures, arrivals, refueling, and port dwell times. The model will identify and analyze a range of domestic vessel types, initially using baseline information on oil-powered ships and comparing them with vessels using alternative fuels. This comparison will allow for an evaluation of energy consumption, operational efficiency, and emissions reductions achievable with different fuel mixes.A key feature of the model will be its ability to estimate energy consumption and emissions under various operating conditions. The model will take into account a broad range of factors, such as cargo weight, vessel type, sea currents, wind conditions, and route specifics to generate highly accurate simulations of energy usage and emissions per voyage. By using advanced modeling techniques, the tool will create a detailed reduced-order model, informed by real-world operational data, which can be generalized and applied across various domestic corridors and routes. This will allow for scalable insights and flexible application, making the tool useful for a variety of real-world shipping scenarios.The role of advanced modeling and simulation is crucial in enabling the detailed analysis required to understand complex maritime operations. The model will simulate dynamic operational events (such as docking, refueling, or delays) and intermodal transport interactions, optimizing freight routing across different transport modes (water, rail, and truck) to minimize overall GHG emissions. This approach allows for a comprehensive, whole-system analysis that considers both direct emissions from maritime transport and indirect emissions from
DA - 2025/01//
PY - 2025
SP - 13
PB - One Petro
UR - https://ww2.arb.ca.gov/sites/default/files/barcu/regact/2021/chc2021/appe.pdf
DO - 10.5957/tos-2025-018
LA - English
KW - Unspecified Feedstock
KW - Marine Diesel Oil (MDO)
KW - Marine Gas Oil (MGO)
KW - Methane (Natural Gas)
KW - Ammonia
KW - Heavy Fuel Oil (HFO)
KW - Unspecified Pathway
KW - Lifecycle Assessment (LCA) and Air Emissions
KW - Ocean-going Vessels
ER -
TI - A Decision Support Tool for Optimizing Fuel Deployment and Emissions Reduction: Advanced Modeling Approach to Sustainable U.S. Maritime Transport
AU - Mesineni, S
AB - The shipping industry, particularly containerized cargo transport, plays a vital role in global trade, but it is also a significant contributor to greenhouse gas (GHG) emissions. With increasing pressure to reduce carbon footprints and achieve sustainability targets, the U.S. maritime sector is seeking innovative solutions to lower its environmental impact. Optimizing fuel usage, improving operational efficiencies, and adopting alternative fuels are essential strategies to decarbonize maritime transport. However, these complex challenges require sophisticated tools for simulating and analyzing different fuel and routing strategies. The US Department of Energy, Advanced Research Projects Agency - Energy funded a project to focuses on developing an advanced decision-support tool to optimize fuel deployment and intermodal freight routing for domestic container shipping in the U.S., aiming to reduce GHG emissions and improve operational efficiency.This project aims to develop an advanced decision-support tool that leverages modeling and simulation to optimize fuel deployment and intermodal freight route planning for domestic container shipping across U.S. maritime corridors. The tool's central goal is to simulate and assess vessel operations, considering both environmental impact and operational efficiency, with a focus on reducing greenhouse gas (GHG) emissions through intelligent fuel selection and optimized routing strategies. The project will integrate traditional oil-based vessel technologies with alternative/Low emission fuels, specifically methanol and ammonia/hydrogen, to evaluate these technologies' potential for decarbonizing the maritime sector.The modeling scope encompasses several critical aspects of container shipping operations: it will simulate container and containership movements across key U.S. maritime routes, including both open sea and inland waterways (e.g., from Los Angeles to Seattle). The simulation will track vessel movements in real-time, incorporating key operational events such as departures, arrivals, refueling, and port dwell times. The model will identify and analyze a range of domestic vessel types, initially using baseline information on oil-powered ships and comparing them with vessels using alternative fuels. This comparison will allow for an evaluation of energy consumption, operational efficiency, and emissions reductions achievable with different fuel mixes.A key feature of the model will be its ability to estimate energy consumption and emissions under various operating conditions. The model will take into account a broad range of factors, such as cargo weight, vessel type, sea currents, wind conditions, and route specifics to generate highly accurate simulations of energy usage and emissions per voyage. By using advanced modeling techniques, the tool will create a detailed reduced-order model, informed by real-world operational data, which can be generalized and applied across various domestic corridors and routes. This will allow for scalable insights and flexible application, making the tool useful for a variety of real-world shipping scenarios.The role of advanced modeling and simulation is crucial in enabling the detailed analysis required to understand complex maritime operations. The model will simulate dynamic operational events (such as docking, refueling, or delays) and intermodal transport interactions, optimizing freight routing across different transport modes (water, rail, and truck) to minimize overall GHG emissions. This approach allows for a comprehensive, whole-system analysis that considers both direct emissions from maritime transport and indirect emissions from
DA - 2025/01//
PY - 2025
SP - 13
PB - One Petro
UR - https://ww2.arb.ca.gov/sites/default/files/barcu/regact/2021/chc2021/appe.pdf
DO - 10.5957/tos-2025-018
LA - English
KW - Unspecified Feedstock
KW - Marine Diesel Oil (MDO)
KW - Marine Gas Oil (MGO)
KW - Methane (Natural Gas)
KW - Ammonia
KW - Heavy Fuel Oil (HFO)
KW - Unspecified Pathway
KW - Lifecycle Assessment (LCA) and Air Emissions
KW - Ocean-going Vessels
ER -