Two sides of the same coin? The Energy Transition Potential in Global North and Global South Countries

Abstract Climatic changes have made transition to renewable energy essential. However, energy transition in the globalized world is challenged with diversification in culture, economic prowess, social development, and state structure. The global negotiations are always tough, among others, due to the split between the Global North (GN) and Global South (GS) countries. At the same time, the debates on how to deal with the inequalities in climate mitigation potential veils a thus far hardly acknowledged difference in energy transition potential and impact in the GN and GS countries. This paper, therefore, aims to contribute to bridging this knowledge gap by making a systematic comparative assessment of energy transition potential in the GN and GS with two regions as example cases. We analysed and compared energy scenarios in two regions in the world: Overijssel representing the GN countries and Matura representing the GS south countries. Both regions are similar in economic activities, but differ in demography and economic development. We analysed and compared the current energy system in both regions and two development scenarios towards 2050: the BAU scenario and the zero emission scenario. Despite the differences in starting position, the energy systems in both regions move towards each other in the longer term, but change pattern and costs differ. In both regions bioresources are the dominant renewable resource in an locally determined energy resource portfolio. However, the costs of getting into this longer term position are significantly higher in Matura than in Overijssel, whereas the general economic potential, as it looks in 2020, is worse in Matura. Our analysis therefore indicates that a renewable energy transition in the longer term can result in zero emission systems in both GN and GS countries, but with substantial differences in costs.

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Energy Production and Consumption Patterns and Planning: A Case of Northeast Minnesota

Energy & Environment ◽

10.1260/095830507781076185 ◽

2007 ◽

Vol 18 (3-4) ◽

pp. 373-392

Author(s):

Felix Amenumey ◽

Melissa Pawlisch ◽

Okechukwu Ukaga

Keyword(s):

Renewable Energy ◽

Energy Production ◽

Energy Resource ◽

Cost Effective ◽

Clean Energy ◽

Energy System ◽

Technical Expertise ◽

Production And Consumption ◽

Energy Projects ◽

Set Up

The Clean Energy Resource Teams (CERTs) is a project designed to give local citizens and other stakeholders a voice in planning and determining their energy future. In total, there are seven CERTs operating in seven regions across Minnesota, USA. CERTs connect citizens with technical expertise to facilitate planning and implementation of energy conservation and renewable energy projects. These technical resources are helping the teams identify and prioritize the most appropriate and cost-effective opportunities within their regions. This paper will describe one of these energy teams (the Northeast CERT) and its efforts in promoting clean energy production and conservation. A key product of the Northeast CERT is a strategic energy plan that highlights the region's top energy priorities. As part of its project priorities, the Northeast Minnesota CERT is working to set up demonstration projects at every school and community in the region. Toward this goal, the team is currently collaborating with two schools in the region to set up renewable energy projects such as wind and solar, which in turn would help students to understand that renewables and conservation can and should be an integral part of our energy system.

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Southern Nevada Renewable Resource Assessment

ASME 2007 Energy Sustainability Conference ◽

10.1115/es2007-36054 ◽

2007 ◽

Author(s):

Allison Gray ◽

Aaron Sahm ◽

Marc Newmarker ◽

Rick Hurt ◽

Robert Boehm ◽

...

Keyword(s):

Renewable Energy ◽

Energy Resource ◽

Renewable Resource ◽

Resource Assessment ◽

National Renewable Energy Laboratory ◽

Renewable Energy Resource ◽

Power Company ◽

Direct Normal Irradiance ◽

Southern Nevada ◽

Energy Center

University of Nevada, Las Vegas Renewable Energy Center (UNLV-REC) currently monitors three meteorological stations in southern Nevada under the direction of the National Renewable Energy Laboratory (NREL) and is funded by the Nevada Southwest Energy Partnership (NSWEP). The three station locations are Eldorado Valley, UNLV-REC Solar Site, and Nevada Power Company Clark Station. The installation dates for each of the locations were October of 2004 for Eldorado Valley station, August of 2003 for the UNLV-REC Solar Site, and March of 2006 for the Nevada Power Clark Station. Publicly available data from each site have been archived since installation completion. This paper discusses the installation of the equipment for each site and images of the setup. The data that is being collected between the sites is also compared. Data comparisons between the sites include net monthly solar energy; monthly peak direct normal irradiance (DNI), average daily wind speed, monthly wind roses, and average monthly dry bulb temperatures. The recently measured data is also compared to resource maps developed by NREL and to TMY data. With these meteorological resources, microclimatic variations can be studied for the area and used as a renewable energy resource for renewable installations in southern Nevada.

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Risk Analysis in Renewable Energy System (RES) Investment for a Developing Country: A Case Study in Pakistan

Arthaniti-Journal of Economic Theory and Practice ◽

10.1177/0976747920910824 ◽

2020 ◽

Vol 19 (2) ◽

pp. 204-223

Author(s):

Izzet Alp Gul ◽

Gülgün Kayakutlu ◽

M. Özgür Kayalica

Keyword(s):

Risk Factors ◽

Renewable Energy ◽

Life Cycle ◽

Risk Analysis ◽

Fossil Fuels ◽

Energy Transition ◽

Energy System ◽

Assessment Model ◽

Infrastructure Investments

Technological improvements allow changing a significant part of the electricity generation investments to renewable energies. Especially in emerging markets and energy import-dependent countries, shift to renewable energy generation became more important to break the links of dependency. Pakistan relies on imported fossil fuels; however, the country’s experience and ambition about the renewable energy transition gain prominence in recent years. Considering the long-term life cycle of energy infrastructure investments, possible risk factors and their dynamic nature must be analysed before the financial decisions are taken. This article aims to propose a system dynamics model for the risk analysis of investment life cycle. In this study, possible risk factors are detected and discussed in different categories. The casual loop diagram of possible risk factors and risk assessment model are designed, and the impacts are analysed. Case study of the proposed model in Pakistan highlighted the importance of commercial risks. The results achieved through this study will guide investors, sector participants and policymakers to develop stable strategies for promoting renewable energy in the country. JEL: Q42, P48, O13

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Latecomers to the Fossil Energy Transition, Frontrunners for Change? The Relevance of the Energy ‘Underdogs’ for Sustainability Transformations

Sustainability ◽

10.3390/su10082650 ◽

2018 ◽

Vol 10 (8) ◽

pp. 2650 ◽

Cited By ~ 3

Author(s):

Anke Schaffartzik ◽

Marina Fischer-Kowalski

Keyword(s):

Renewable Energy ◽

Emerging Economies ◽

Fossil Fuel ◽

Energy Transition ◽

Energy System ◽

Fossil Energy ◽

System A ◽

Traditional Patterns ◽

Big Push ◽

Global Population

The global energy system subsumes both extreme wealth (and waste) and extreme poverty. A minority of the global population is consuming the majority of the fossil fuel-based energy and causing global warming. While the mature industrialized economies maintain their high levels of energy consumption, the emerging economies are rapidly expanding their fossil energy systems, emulating traditional patterns of industrialization. We take a global, socio-metabolic perspective on the energy transition phases—take-off, maturation, and completion—of 142 countries between 1971 and 2015. Even within our global fossil energy system, the transition to fossil energy is still ongoing; many countries are in the process of replacing renewable energy with fossil energy. However, due to globally limited supplies and sinks, continuing the fossil energy transition is not an indefinite option. Rather than a “Big Push” for renewable energy within pockets of the fossil energy system, a sustainability transformation is required that would change far more than patterns of energy supply and use. Where this far-reaching change requires pushing back against the fossil energy system, the energy underdogs—the latecomers to the fossil energy transition—just might come out on top.

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Can the 1.5 ℃ warming target be met in a global transition to 100% renewable energy?

AIMS Energy ◽

10.3934/energy.2021054 ◽

2021 ◽

Vol 9 (6) ◽

pp. 1170-1191

Author(s):

Peter Schwartzman ◽

◽

David Schwartzman ◽

Keyword(s):

Carbon Dioxide ◽

Renewable Energy ◽

Carbon Dioxide Emissions ◽

Energy Demand ◽

Fossil Fuels ◽

Energy Transition ◽

Climate Mitigation ◽

Energy Poverty ◽

Global Energy ◽

Mitigation And Adaptation

<abstract> First, we recognize the valuable previous studies which model renewable energy growth with complete termination of fossil fuels along with assumptions of the remaining carbon budgets to reach IPCC warming targets. However, these studies use very complex combined economic/physical modeling and commonly lack transparency regarding the sensitivity to assumed inputs. Moreover, it is not clear that energy poverty with its big present impact in the global South has been eliminated in their scenarios. Further, their CO2-equivalent natural gas emission factors are underestimated, which will have significant impact on the computed greenhouse gas emissions. Therefore, we address this question in a transparent modeling study: can the 1.5 ℃ warming target still be met with an aggressive phaseout of fossil fuels coupled with a 100% replacement by renewable energy? We compute the continuous generation of global wind/solar energy power along with the cumulative carbon dioxide equivalent emissions in a complete phaseout of fossil fuels over a 20 year period. We compare these computed emissions with the state-of-the-science estimates for the remaining carbon budget of carbon dioxide emissions consistent with the 1.5 ℃ warming target, concluding that it is still possible to meet this warming target if the creation of a global 100% renewable energy transition of sufficient capacity begins very soon which will likely be needed to power aggressive negative carbon emission technology. The latter is focused on direct air capture for crustal storage. More efficient renewable technologies in the near future will make this transition easier and promote the implementation of a global circular economy. Taking into account technological improvements in 2nd law (exergy) efficiencies reducing the necessary global energy demand, the renewable supply should likely be no more than 1.5 times the present level, with the capacity to eliminate global energy poverty, for climate mitigation and adaptation. </abstract>

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Legal Provisions and Market Conditions for Energy Communities in Austria, Germany, Greece, Italy, Spain, and Turkey: A Comparative Assessment

Sustainability ◽

10.3390/su132011212 ◽

2021 ◽

Vol 13 (20) ◽

pp. 11212

Author(s):

Mehmet Efe Biresselioglu ◽

Siyami Alp Limoncuoglu ◽

Muhittin Hakan Demir ◽

Johannes Reichl ◽

Katrin Burgstaller ◽

...

Keyword(s):

Climate Change ◽

Renewable Energy ◽

Social Acceptance ◽

Energy Transition ◽

Active Role ◽

Energy System ◽

The European Union ◽

Horizon 2020 ◽

Legal Provisions ◽

The Eu

The Climate Pact and the European Green Deal constitute the main components of the European Union (EU)’s climate change policy. Energy transition, that is, transformation to a zero-carbon global energy system, is one of the main pillars of climate change mitigation policies. This transformation, coupled with the empowerment of individuals within the energy system, shifts citizens from their roles as customers towards a more active role. Within this framework, energy communities stand out as significant facilitators for the participation of individuals and communities in the energy system, promoting self-consumption and contributing to the social acceptance of renewable energy initiatives, among other direct and indirect benefits. The main directives introducing energy communities into the EU legal system are RED II and ED 2019. This study, conducted as a part of a Horizon 2020-funded eCREW project, assessed the adaptability and implementability of these two directives within national legislation, along with the associated legal and administrative frameworks, utilizing evidence from Austria, Germany, Greece, Italy, Spain, and Turkey. The comparative analysis also enhances the understanding of the concept of renewable energy communities and citizen energy communities, both in the EU and in nonmember countries. The results of the analysis revealed that none of the countries studied had yet completed the process of harmonizing their legislation concerning energy communities.

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Integrated Renewable Energy Systems in Fruit and Vegetable Processing Industries: A Systematic Review

European Journal of Energy Research ◽

10.24018/ejenergy.2021.1.3.13 ◽

2021 ◽

Vol 1 (3) ◽

pp. 1-12

Author(s):

Sofia Lewis Lopes ◽

Elizabeth Duarte ◽

Rita Fragoso

Keyword(s):

Renewable Energy ◽

Business Models ◽

Energy Systems ◽

Energy Transition ◽

Energy System ◽

Fruit And Vegetable ◽

Energy Technologies ◽

Waste Production ◽

New Business ◽

Exponential Population Growth

The exponential population growth will put great pressure on natural resources, agriculture, energy systems and waste production. New business models and innovative technological approaches are necessary to tackle these challenges and achieve the energy transition targets set by the European Commission. Renewable energy technologies and processes such as solar photovoltaic, solar thermal and anaerobic co-digestion have become a subject of interest and research as a solution that could be fully implemented in industries and solve several environmental and economic problems. This paper discusses the possibility of integrating and complement these technologies to maximize renewable energy production and circularity. The review was performed with a funnel approach aiming to analyze broad to specific subjects. Beginning with a literature review on the various definitions of circular economy, bioeconomy, and circular bioeconomy, ultimately proposing a single definition according to an industrial and academic scope combination, followed by a systematization and assessment of data and literature regarding energy systems present state and projections. The next phase was to assess data and literature of the fruit and vegetable processing industry from an energy consumption and biowaste production perspective to consequently discussing technologies that could help manage problems identified throughout this review. This paper culminates in propounding an Integrated Renewable Energy System conceptual model that promotes energy and waste circularity, envisioning how industries could be designed or redesigned in the future, coupled with a circular bioeconomy business model.

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Energy transition and willingness to pay for renewable energy: The case of environmental students

IOP Conference Series Earth and Environmental Science ◽

10.1088/1755-1315/899/1/012048 ◽

2021 ◽

Vol 899 (1) ◽

pp. 012048

Author(s):

Evangelia Karasmanaki

Keyword(s):

Social Media ◽

Renewable Energy ◽

Willingness To Pay ◽

Energy Production ◽

Fossil Fuels ◽

Renewable Energy Sources ◽

Energy Transition ◽

Energy System ◽

Electricity Production ◽

Energy Sources

Abstract Examining willingness-to-pay (WTP) for renewable energy sources (RES) as well as views on energy topics can enable policymakers to design effective measures for facilitating the transition from fossil fuels to a renewable-based energy system. The aim of this study was to investigate environmental students’ willingness-to-pay for renewables and their views on various energy topics. Results showed that respondents preferred renewable-based electricity production to conventional energy production while solar energy emerged as the most preferred renewable type. In addition, most respondents were willing to pay for renewable energy but would pay relatively low sums of money per month. Moreover, respondents were divided over whether new lignite plants should be constructed in Greece. Finally, social media and special websites were the most favored media of daily information.

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ANALYSIS OF WAYS FOR DECARBONIZATION OF THE EU HEATING SECTOR (REVIEW)

Thermophysics and Thermal Power Engineering ◽

10.31472/ttpe.4.2020.11 ◽

2020 ◽

Vol 42 (4) ◽

pp. 93-101

Author(s):

T.A. Zheliezna ◽

A.I. Bashtovyi

Keyword(s):

Renewable Energy ◽

Heat Supply ◽

New Technologies ◽

Renewable Energy Sources ◽

District Heating ◽

Energy Transition ◽

Energy System ◽

Green Energy ◽

Heating Systems ◽

The Eu

The aim of the work is to analyze possible ways of decarbonization of the EU heat supply sector. The task of the work is to identify the most promising areas and develop appropriate recommendations for Ukraine. The heat supply sector of the EU and Ukraine needs decarbonization, for which there is a big potential and different areas of implementation of relevant measures. In Europe, such a strategy is set out in the Roadmap for decarbonization of the EU heating sector until 2050, the main provisions of which are in line with objectives of the European Green Deal and the EU Strategy on Heating and Cooling. European experts have developed the concept of a smart energy system, which was taken into account when preparing the Roadmap for decarbonization of the EU heating sector until 2050. A number of carried out studies have shown that a smart energy system with 50% district heating integrated with other parts of the overall energy system is more efficient than a conventional energy system or the one based on decentralized heat supply, in terms of the possibility of using a high share of renewable energy. It is recommended for Ukraine to finalize the Concept of green energy transition until 2050, taking into account European approaches to the development of heating systems and the use of modern biofuels. It is also recommended to expand the current Concept of heat supply of Ukraine to the level of a strategy with an emphasis on the development of district heating systems, wide involvement of renewable energy sources and new technologies.

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Pathway Analysis of a Zero-Emission Transition in the Nordic-Baltic Region

Energies ◽

10.3390/en12173337 ◽

2019 ◽

Vol 12 (17) ◽

pp. 3337 ◽

Cited By ~ 8

Author(s):

Peter D. Lund ◽

Klaus Skytte ◽

Simon Bolwig ◽

Torjus Folsland Bolkesjö ◽

Claire Bergaentzlé ◽

...

Keyword(s):

Renewable Energy ◽

Pathway Analysis ◽

Large Scale ◽

Energy Use ◽

Energy System ◽

Carbon Price ◽

System Modelling ◽

Baltic Region ◽

Emission Pathway ◽

Zero Emission

A zero-emission pathway for the Nordic and Baltic region in Europe is described based on the comprehensive policy and scenario analyses, accompanied by energy system modelling. The analyses show that a least-cost strategy would massively employ renewable energy, particularly in the power sector. Through strong coupling across energy sectors and countries, electricity would play a central role in the decarbonization of the main energy sectors. In particular power-to-heat conversion, where heat storage appears important in addition to existing hydropower. Technical and regulatory barriers in front of increased sector coupling and flexibility were identified, and policy measures are proposed to overcome these. In addition to a high carbon price, dynamic tariffs and taxation of electricity would be important to allow market signals for flexibility to reach end-users. A stronger power transmission connection from the Nordics to the mainland-Europe and the United Kingdom would be beneficial for the emission reductions and renewable energy use. The transition pathway analysis points out socio-technical issues such as social acceptance of large-scale new infrastructures (e.g., wind, cables). The energy system optimizations indicate that most of the investments needed for the zero-emission pathway until 2050 would take place already by 2030.

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