Green port development in Hong Kong - reduction of marine and port-related emissions

The Conference proceedings' website is located at http://www.hsmc.edu.hk/images/scm_CallForPaper/Conference%20Proceedings.pdfThe impact of air pollutant emissions from shipping and port operations towards environment and health is a pressing global concern. The marine and port sectors have contributed significantly to the growth of the supply chain industry and the economic development, while, at the same time, the pollutant emissions rising from ships and port-related operations have inflicted adverse public health concerns. Leading ports and terminals continuously impose measures to reduce the greenhouse gas emitted during vessel berthing. Hong Kong, being the third largest container port in the world and having the second cruise terminal running into operation, urgently requires comprehensive green port operations and practices. This paper evaluates and benchmarks the latest measures conducted by the leading ports over the world in reducing the greenhouse gas emissions from ship and port operations. International regulations, onshore power supply, vessel speed reduction, and fuel switching are analyzed. Recommendations on the future green port development in Hong Kong are proposed.postprin

Modeling Bioenergy Supply Chains: Feedstocks Pretreatment, Integrated System Design Under Uncertainty

Biofuels have been promoted by governmental policies for reducing fossil fuel dependency and greenhouse gas emissions, as well as facilitating regional economic growth. Comprehensive model analysis is needed to assess the economic and environmental impacts of developing bioenergy production systems. For cellulosic biofuel production and supply in particular, existing studies have not accounted for the inter-dependencies between multiple participating decision makers and simultaneously incorporated uncertainties and risks associated with the linked production systems.This dissertation presents a methodology that incorporates uncertainty element to the existing integrated modeling framework specifically designed for advanced biofuel production systems using dedicated energy crops as feedstock resources. The goal of the framework is to support the bioenergy industry for infrastructure and supply chain development. The framework is flexible to adapt to different topological network structures and decision scopes based on the modeling requirements, such as on capturing the interactions between the agricultural production system and the multi-refinery bioenergy supply chain system with regards to land allocation and crop adoption patterns, which is critical for estimating feedstock supply potentials for the bioenergy industry. The methodology is also particularly designed to incorporate system uncertainties by using stochastic programming models to improve the resilience of the optimized system design.The framework is used to construct model analyses in two case studies. The results of the California biomass supply model estimate that feedstock pretreatment via combined torrefaction and pelletization reduces delivered and transportation cost for long-distance biomass shipment by 5% and 15% respectively. The Pacific Northwest hardwood biofuels application integrates full-scaled supply chain infrastructure optimization with agricultural economic modeling and estimates that bio-jet fuels can be produced at costs between 4 to 5 dollars per gallon, and identifies areas suitable for simultaneously deploying a set of biorefineries using adopted poplar as the dedicated energy crop to produce biomass feedstocks. This application specifically incorporates system uncertainties in the crop market and provides an optimal system design solution with over 17% improvement in expected total profit compared to its corresponding deterministic model

Chapter 4: Infrastructure Considerations for CO2 Utilization, in: Carbon Dioxide Utilization Markets and Infrastructure Status and Opportunities: A First Report

This chapter describes considerations for developing infrastructure for carbon dioxide (CO2) utilization, taking into account the CO2-derived products identified in Chapter 3 and the existing infrastructure discussed in Chapter 2. Infrastructure needs throughout the CO2 utilization value chain are examined, from capture to purification, transportation, conversion, and, where applicable, transportation of the CO2-derived product. Requirements for enabling infrastructure, namely, clean electricity, hydrogen, water, land, and energy storage, are also considered

Towards the IMO’s GHG goals: a critical overview of the perspectives and challenges of the main options for decarbonizing international shipping

The Initial Strategy on reduction of greenhouse gas (GHG) emissions from ships adopted by the International Maritime Organization (IMO) in 2018 commits the IMO to reduce total GHG emissions of shipping by at least 50% by 2050. Though the direction of the Strategy is clear, the path to implementation remains uncertain. The ambitious IMO’s target calls for widespread uptake of lower and zero-carbon fuels, in addition to other energy eciency measures, including operational and market ones. Using a triangulated research approach, this paper provides a critical overview of the main measures and initiatives the shipping industry can adopt to try to cope with the new IMO’s requirements. The pros and cons of the most popular emission reduction options are investigated along with the main challenges and barriers to implementation and the potential facilitators that could foster a wider application. The framework that is outlined is complex and not without controversy. Research can play a key role as a facilitator of shipping’s decarbonization by providing its contribution to overcoming the existing controversies on various decarbonization options and by developing a wealth of knowledge that can encourage the implementation of low-carbon initiatives

Smart Steaming: A New Flexible Paradigm for Synchromodal Logistics

Slow steaming, i.e., the possibility to ship vessels at a significantly slower speed than their nominal one, has been widely studied and implemented to improve the sustainability of long-haul supply chains. However, to create an efficient symbiosis with the paradigm of synchromodality, an evolution of slow steaming called smart steaming is introduced. Smart steaming is about defining a medium speed execution of shipping movements and the real-time adjustment (acceleration and deceleration) of traveling speeds to pursue the entire logistic system’s overall efficiency and sustainability. For instance, congestion in handling facilities (intermodal hubs, ports, and rail stations) is often caused by the common wish to arrive as soon as possible. Therefore, smart steaming would help avoid bottlenecks, allowing better synchronization and decreasing waiting time at ports or handling facilities. This work aims to discuss the strict relationships between smart steaming and synchromodality and show the potential impact of moving from slow steaming to smart steaming in terms of sustainability and efficiency. Moreover, we will propose an analysis considering the pros, cons, opportunities, and risks of managing operations under this new policy

The Role of Green and Blue Hydrogen in the Energy Transition - A Technological and Geopolitical Perspective

Hydrogen is currently enjoying a renewed and widespread momentum in many national and international climate strategies. This review paper is focused on analysing the challenges and opportunities that are related to green and blue hydrogen, which are at the basis of different perspectives of a potential hydrogen society. While many governments and private companies are putting significant resources on the development of hydrogen technologies, there still remains a high number of unsolved issues, including technical challenges, economic and geopolitical implications. The hydrogen supply chain includes a large number of steps, resulting in additional energy losses, and while much focus is put on hydrogen generation costs, its transport and storage should not be neglected. A low-carbon hydrogen economy offers promising opportunities not only to fight climate change, but also to enhance energy security and develop local industries in many countries. However, to face the huge challenges of a transition towards a zero-carbon energy system, all available technologies should be allowed to contribute based on measurable indicators, which require a strong international consensus based on transparent standards and targets

Breaking the barriers : operational measures for the decarbonization of shipping : a study on barriers to operational energy efficiency measures

Energy efficiency is a key strategy to address the issue of climate change. Operational measures that increase energy efficiency are widely used in shipping, but there is evidence of a gap between the actual implementation level and what would be optimal. This is dubbed the energy efficiency gap. This paper aims to examine which barriers are responsible for the energy efficiency gap in deep-sea shipping and how policy intervention can mitigate it. Contributing to the literature on operational energy efficiency measures in shipping, we look to former studies and synthesize former research results to give a comprehensive overview of the subject. Further, we contribute to the literature by analyzing four existing and potential policy regulations and investigating their likely effect on the industry and the energy efficiency gap. This will give a firm foundation for advancing knowledge, facilitating theory development, providing a unifying status check on operational measures, and how policy instruments can affect the uptake of these measures. Our analysis also identifies areas where the current and proposed industry regulations seem insufficient to drive change and where other or stricter policy instruments may be required. Our findings suggest that split incentives and imperfect information are the main barriers to closing the energy efficiency gap for operational measures in shipping. Policy instruments can help facilitate the uptake of these measures if designed correctly. However, our findings suggest that none of the four regulations addressed in this thesis are likely to solve the problem with a lack of reliable information. Further, MBMs can make monetary savings from reduced emissions more substantial than today and give incentives to reduce emissions. However, contractual clauses and the presence of other market barriers can limit the MBMs effect on vessels’ behavior. Consequently, to significantly reduce the emissions from shipping, we argue that the industry should be focusing on finding ways to improve the quality of information about vessels’ performance regarding energy efficiency and on exploring new contractual structures. Keywords – Sustainable shipping, energy efficiency, operational measures, IMO, GHG, operational efficiency.nhhma

Benefits and Costs of Diversification in the European Natural Gas Market

Die Dissertationsschrift thematisiert die Frage nach den Kosten und Nutzen einer Diversifikationsstrategie im europäischen Erdgasmarkt und gliedert sich in neun Kapitel. In einer Vorbetrachtung beschreiben die Kapitel eins bis vier die Ausganglage mit Blick auf Angebots- und Nachfragestrukturen sowie der Gasinfrastruktur. Unsicherheiten in Bezug auf die Entwicklung der Nachfrage, Importverfügbarkeit und Preisniveaus werden diskutiert. In einem analytischen Rahmen wird das Thema Diversifikation in den Kontext der Energiesicherheit eingeordnet. Die Kapitel fünf bis sieben befassen sich mit der Beschreibung und der Analyse des europäischen Gasmarkts. Dafür wird ein lineares Modell, GAMAMOD-EU, entwickelt, welches als stochastische Optimierung den Ausbau der Erdgasinfrastruktur unter Einbezug von drei Unsicherheitsdimensionen in den Jahren 2030 und 2045 abbildet. Zusätzlich werden drei Diversifikationsstrategien in Hinblick auf Infrastrukturentwicklung und Versorgungssicherheit analysiert. In einer Erweiterung wird der Import Grüner Gase in die Betrachtung einbezogen. Kapitel acht stellt das deutsche Gasnetzmodell GAMAMOD-DE mit einer Fallstudie vor, die die Versorgungslage im kalten Winter 2012 nachmodelliert. Im abschließenden Kapitel neun werden die zu Beginn aufgeworfenen Forschungsfragen beantwortet, politische Handlungsempfehlungen gegeben und der weitere Forschungsbedarf skizziert.:Table of Contents List of Figures List of Tables Abbreviations Country Codes Nomenclature: GAMAMOD-EU Nomenclature: GAMAMOD-DE 1 Introduction 2 Uncertainties in Gas Markets 3 Diversification in Gas Markets to Ensure Security of Supply 4 Natural Gas Infrastructure 5 The European Natural Gas Market Model (GAMAMOD-EU) 6 Results on Security of Supply in the European Gas Market 7 Impact of Green Gas Imports on Infrastructure Investments 8 The German Natural Gas Market Model (GAMAMOD-DE) 9 Conclusion and Outlook Laws and Communication Papers References AppendixThe dissertation addresses the question of the costs and benefits of a diversification strategy in the European natural gas market and is divided into nine chapters. In a preliminary analysis, chapters one to four describe the initial situation with regard to supply and demand structures as well as the gas infrastructure. Uncertainties regarding the development of demand, import availability and price levels are discussed. In an analytical framework, the topic of diversification is placed in the context of energy security. Chapters five to seven deal with the description and analysis of the European gas market. For this purpose, a linear model, GAMAMOD-EU, is developed, which maps the expansion of the natural gas infrastructure as a stochastic optimisation, taking into account three uncertainty dimensions in the years 2030 and 2045. In addition, three diversification strategies are analysed with regard to infrastructure development and security of supply. In an extension, the import of green gases is included in the analysis. Chapter eight presents the German gas grid model GAMAMOD-DE with a case study, which models the supply situation in the cold winter of 2012. In the concluding chapter nine, the research questions raised at the beginning are answered, political recommendations for action are given and the need for further research is outlined.:Table of Contents List of Figures List of Tables Abbreviations Country Codes Nomenclature: GAMAMOD-EU Nomenclature: GAMAMOD-DE 1 Introduction 2 Uncertainties in Gas Markets 3 Diversification in Gas Markets to Ensure Security of Supply 4 Natural Gas Infrastructure 5 The European Natural Gas Market Model (GAMAMOD-EU) 6 Results on Security of Supply in the European Gas Market 7 Impact of Green Gas Imports on Infrastructure Investments 8 The German Natural Gas Market Model (GAMAMOD-DE) 9 Conclusion and Outlook Laws and Communication Papers References Appendi

Transport mode and network architecture : carbon footprint as a new decision metric

Thesis (M. Eng. in Logistics)--Massachusetts Institute of Technology, Engineering Systems Division, 2008.Includes bibliographical references (leaves 132-133).This thesis examines the tradeoffs between carbon footprint, cost, time and risk across three case studies of United States' perishable or consumer packaged goods firms and their transportation partners. Building upon previous research, and utilizing an Institute of Management and Administration (IOMA) and MIT Center for Transportation and Logistics (CTL) survey of supply chain professionals, the goal of this thesis is to better understand the decision process and motivations of our case study companies with regard to carbon footprint and implications for transport mode and network architecture, and the tradeoffs involved in making these decisions. We examine: (1) An expedited refrigerated rail service providing coast-to-coast shipment of produce for a major retailer, in lieu of its prior trucking arrangement; (2) A dairy producer which with the help of its trucking partner switched from less-than-truckload (LTL) to full truckload (FTL) and currently explore the possibility to re-organize its distribution network; and (3) A bottled water firm which created an additional container shipping route to reduce the volume of water it ships via truck. Comparisons and contrasts are made between case study firms. Findings from these case studies are used to make forward-looking recommendations for companies interested in altering transport mode and/or network architecture as a means of reducing the carbon footprint of their operations.by Nelly Andrieu and Lee Weiss.M.Eng.in Logistic

Beyond Gridlock

Private climate governance can achieve major greenhouse gas (“GHG”) emissions reductions while governments are in gridlock. Despite the optimism that emerged from the Earth Summit in Rio de Janeiro, Brazil in 1992, almost a quarter century later the federal legislative process and international climate negotiations are years from a comprehensive response. Yet Microsoft, Google and many other companies have committed to become carbon neutral. Wal-Mart has partnered with the Environmental Defense Fund to secure 20 million tons of GHG emissions reductions from its suppliers around the world, an amount equal to almost half the emissions from the US iron and steel industry. Investors holding roughly $90 trillion in assets have pressured large corporations to disclose and reduce their carbon footprints, and participating companies report having reduced emissions by an amount equal to a major emitting nation. Private forest certification programs have taken steps to reduce the GHG emissions from deforestation. Household carbon regulation is off the table in many countries, but private advocacy groups and corporations have reduced household emissions through home energy disclosure, eco-driving campaigns, employee programs, voluntary carbon offsets, and other initiatives. To explain the importance of private climate governance, this Article is structured around three propositions. The first is the need for urgency... The second proposition is that the barriers to adopting and implementing a carbon price are unlikely to be overcome in the next decade... The third proposition is that unlocking the potential of private governance will require a conceptual shift by scholars, philanthropists, and corporate and NGO managers... Private initiatives cannot keep global emissions on track to achieve the most widely adopted climate target, but they can achieve a private governance wedge: they can reduce emissions by roughly 1,000 million tons (a gigaton) of CO2 per year between 2016 and 2025. When combined with other efforts, this private governance wedge offers a reasonable chance of buying a decade to resolve the current government gridlock