Driving the development of energy communities in Colombia: challenges and opportunities for a decentralized energy transition

Evaluating Normandy’s sustainable development and energy transition policies

Latest advancements and challenges of technologies and methods for accelerating the sustainable energy transition

Business models for energy communities: A review of key issues and trends

Human history has been the story of the constant search for energy, e.g., in terms of food conversion to energy. Early on in its origins, humankind has had to satisfy its energy demand through available energy resources. Although the use of non-renewable energy sources has been perpetuated over time, there are currently many strategies implemented by states to develop energy transition for sustainable development. An example of this is the emergence of decentralization initiatives such as prosumers and energy communities. Within the European Union, the Directives 2018/2001 and 2019/944 open a broad regulatory framework for this type of practice. In the face of the challenges imposed by the so-called energy transition towards more environmentally friendly forms of energy (= ‘green energy’) and climate change, energy democracy plays a key role. These initiatives have currently yielded important results where individuals and communities have become increasingly empowered and have become important actors in energy generation from renewable energy sources. The general objective of this research is to substantiate the need for decentralized energy generation transitions. The main results of the research are the assessment of the legal framework for initiatives in decentralized energy generation in the European Union and the identification of good practices in the European context. energy decentralization initiatives, sustainable energy development, European Union, Energy Law, Energy Policy, energy prosumerism, energy communities, EU Law, energy market, energy consumer empowerment

Introduction. The article is devoted to the current issues of global low-carbon development, the concept of the evolution of the transition between different stages of low-carbon transformation of the economy, development strategies of countries, society and the world, research into the impact of the economic development model on achieving the goal of climate neutrality and scenarios of energy and digital transitions on this path. The purpose of the article is to systematize logically consistent connections between the concept of the evolution of low-carbon transformation of global development and scenarios of energy and technological/digital transformations. Research methods. When writing the scientific article, the dialectical method of scientific cognition, methods of scientific abstraction, analysis and synthesis; systematic generalization; comparative analysis, statistical analysis were used. Results. The hypothesis of the existence of connections between the concept of evolution of lowcarbon transformation of global development and scenarios of energy and technological/digital transformations is proven on the basis of systematization and generalization of interdisciplinary research on the concepts of sustainable development, climate neutrality, low-carbon development, forecasts and scenarios of energy and digital transitions. The work summarizes the phases of low-carbon development, the connections between the categories of ―low-carbon energy‖, ―low-carbon life‖, ―low-carbon society‖, ―low-carbon city‖, ―low-carbon community‖, ―low-carbon world‖. Based on the energy transition scenarios proposed by S&P Global Commodity Insights, conclusions are drawn about possible scenarios of the transition from the initial to the developed phase of low-carbon development. The ways of digital transformations are summarized, which should ensure greater efficiency of the transition to the mature phase of low-carbon development. Conclusions. The main provisions of this article will contribute to the formation of a state policy for economic recovery based on the principles of "Build Back Better" and "Build Back Greener", taking into account the scenarios of the global energy transition and theoretical concepts of the evolution of low-carbon development. Keywords: low-carbon development, climate neutrality, energy, energy transition, digital transformation.

Local energy transitions as process: How contract management problems stymie a city's sustainable transition to renewable energy

Editorial: Governing the EU's climate and energy transition through the 2030 Framework

Energy communities are a promising strategy for a global energy transition. European Union (EU) regulatory frameworks are already established and clearly explained, aiming to develop as many projects as possible in the different European countries. Accordingly, it is necessary to present two different types of countries: the laggards and the pioneers, two categories that highlight the discrepancies in policy, bureaucracy, culture, and usage of alternative sources and technologies, such as renewable energy, towards the implementation of energy communities. This work compares two representative case studies to qualitatively understand the differences between laggard and pioneer countries: Italy and the Netherlands, respectively. The regulatory framework and the solid points/shortcomings of each country are explained first. Thereafter, an accurate description of the two selected case study communities and their different peculiarities is provided. Finally, the main similarities and differences are stressed to discuss the lessons to be learned in laggard and pioneer countries. Five pillars for the development and uptake of energy communities are identified related to regulations, economic benefits, technical limitations, sustainability, and social awareness. These outcomes suggest the importance of policy management, and stress the limitations of governance in helping policymakers and experts to support the energy transition.

EU has set ambitious commitment to achieve low carbon energy and economy transition up to 2050. This low carbon transition means sustainable energy development path based on renewable energy sources and first of all should address the energy poverty vulnerability and justice issues. The main goal of the paper is to develop indicators framework for assessing low carbon just energy transition and to apply this framework for analysis how climate change mitigation policies in households targeting enhancement of energy renovation of residential buildings and promotion of the use of micro-generation technologies and other policies are affecting household’s energy poverty and vulnerability in selected countries: Lithuania and Greece. This framework allows to assess three main dimensions of sustainable energy development: environmental, social and economic. The paper provides policy recommendations how to deal with just low carbon energy transition which means addressing energy poverty issues during moving to 100% renewables in power generation based on performed case studies.

The greatest sustainability challenge facing humanity today is the greenhouse gas emissions and the global climate change with fossil fuels led by coal, natural gas and oil contributing 61.3% of global electricity generation in the year 2020. The cumulative effect of the Stockholm, Rio, and Johannesburg conferences identified sustainable energy development (SED) as a very important factor in the sustainable global development. This study reviews energy transition strategies and proposes a roadmap for sustainable energy transition for sustainable electricity generation and supply in line with commitments of the Paris Agreement aimed at reducing greenhouse gas emissions and limiting the rise in global average temperature to 1.5°C above the preindustrial level. The sustainable transition strategies typically consist of three major technological changes namely, energy savings on the demand side, generation efficiency at production level and fossil fuel substitution by various renewable energy sources and low carbon nuclear. For the transition remain technically and economically feasible and beneficial, policy initiatives are necessary to steer the global electricity transition towards a sustainable energy and electricity system. Large-scale renewable energy adoption should include measures to improve efficiency of existing nonrenewable sources which still have an important cost reduction and stabilization role. A resilient grid with advanced energy storage for storage and absorption of variable renewables should also be part of the transition strategies. From this study, it was noted that whereas sustainable development has social, economic, and environmental pillars, energy sustainability is best analysed by five-dimensional approach consisting of environmental, economic, social, technical, and institutional/political sustainability to determine resource sustainability. The energy transition requires new technology for maximum use of the abundant but intermittent renewable sources a sustainable mix with limited nonrenewable sources optimized to minimize cost and environmental impact but maintained quality, stability, and flexibility of an electricity supply system. Technologies needed for the transition are those that use conventional mitigation, negative emissions technologies which capture and sequester carbon emissions and finally technologies which alter the global atmospheric radiative energy budget to stabilize and reduce global average temperature. A sustainable electricity system needs facilitating technology, policy, strategies and infrastructure like smart grids, and models with an appropriate mix of both renewable and low carbon energy sources.

Advancing local energy transitions: A global review of government instruments supporting community energy

Role of sharing economy in energy transition and sustainable economic development in China

Global Development, Converging Divergence and Development Studies: A Rejoinder

The goals of the European Union towards the energy transition imply profound changes in the energy field, so as to promote sustainable energy development while fostering economic growth. To achieve these changes, the incorporation of sustainable technologies supporting decentralisation, energy efficiency, renewable energy production, and demand flexibility is of vital importance. Blockchain has the potential to change energy services towards this direction. To optimally exploit blockchain, innovative business models need to be designed, identifying the opportunities emerging from unmet needs, while also considering potential risks so as to take action to overcome them. In this context, the scope of this paper is to examine the opportunities and the risks that emerge from the adoption of blockchain in four innovative business models, while also identifying mitigation strategies to support and accelerate the energy transition, thus proposing optimal approaches of exploitation of blockchain in energy services. The business models concern Energy Performance Contracting with P4P guarantees, improved self-consumption in energy cooperatives, energy efficiency and flexibility services for natural gas boilers, and smart energy management for EV chargers and HVAC appliances. Firstly, the value proposition of the business models is analysed and results in a comprehensive SWOT analysis. Based on the findings of the analysis and consultations with relevant market actors, in combination with the examination of the relevant literature, risks are identified and evaluated through a qualitative assessment approach. Subsequently, specific mitigation strategies are proposed to address the detected risks. This research demonstrates that blockchain integration into these business models can significantly improve energy efficiency, reduce operational costs, enhance security, and support a more decentralised energy system, providing actionable insights for stakeholders to implement blockchain solutions effectively. Furthermore, according to the results, technological and legal risks are the most significant, followed by political, economic, and social risks, while environmental risks of blockchain integration are not as important. Strategies to address risks relevant to blockchain exploitation include ensuring policy alignment, emphasising economic feasibility, facilitating social inclusion, prioritising security and interoperability, consulting with legal experts, and using consensus algorithms with low energy consumption. The findings offer clear guidance for energy service providers, policymakers, and technology developers, assisting in the design, deployment, and risk mitigation of blockchain-enabled business models to accelerate sustainable energy development.

This paper studies the real-time energy trading problem in a smart community consisting of a group of grid-connected prosumers with controllable loads, renewable generations and energy storage systems. We propose a peer-to-peer (P2P) energy trading system, which integrates energy trading with energy management, enabling each prosumer to jointly manage its energy consumption, storage scheduling and energy trading in a dynamic manner for smart communities consisting of a group of grid-connected prosumers with controllable loads, renewable generations and energy storage systems. The proposed community-based P2P energy trading system combines an online energy control and trading algorithm with a double auction mechanism. The energy control and trading algorithm is designed based on the Lyapunov theory, allowing each prosumer to independently determine its bid in each time slot only based on its current energy supply condition, while the trading price, which is determined via the double auction mechanism, reflects the collective energy supply conditions of all prosumers participating in energy trading. The integration of the Lyapunov-based energy control and trading algorithm and the double auction mechanism yields a dynamic energy trading pricing mechanism that induces the prosumers to participate in energy trading in a coordinated manner by influencing the energy consumption, energy charging/discharging and energy trading decisions of the prosumers. Numerical simulation results demonstrate that energy exchange in the proposed scalable energy trading system yields significant improvements in terms of energy cost savings and renewable energy utilization efficiency, while ensuring the fair sharing of the benefits reaped from energy trading among the prosumers.