Exploring Energy Pathways for the Low-Carbon Transformation in India—A Model-Based Analysis

With an increasing expected energy demand and current dominance of coal electrification, India plays a major role in global carbon policies and the future low-carbon transformation. This paper explores three energy pathways for India until 2050 by applying the linear, cost-minimizing, global energy system model (GENeSYS-MOD). The benchmark scenario “limited emissions only” (LEO) is based on ambitious targets set out by the Paris Agreement. A more conservative “business as usual” (BAU) scenario is sketched out along the lines of the New Policies scenario from the International Energy Agency (IEA). On the more ambitious side, we explore the potential implications of supplying the Indian economy entirely with renewable energies with the “100% renewable energy sources” (100% RES) scenario. Overall, our results suggest that a transformation process towards a low-carbon energy system in the power, heat, and transportation sectors until 2050 is technically feasible. Solar power is likely to establish itself as the key energy source by 2050 in all scenarios, given the model’s underlying emission limits and technical parameters. The paper concludes with an analysis of potential social, economic and political barriers to be overcome for the needed Indian low-carbon transformation.

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Research Design, Scoping Tools, and Preview

Low Carbon Energy Transitions ◽

10.1093/oso/9780199362554.003.0006 ◽

2018 ◽

Author(s):

Kathleen Araújo

Keyword(s):

Fossil Fuels ◽

International Energy Agency ◽

Field Work ◽

Energy System ◽

Oil Shocks ◽

Low Carbon ◽

Energy Agency ◽

Technology Learning ◽

Energy Technologies ◽

Low Carbon Energy

This chapter outlines the design of the current study. It discusses my underlying logic for scoping energy system change with theory-building in the form of (1) a framework on intervention that operationalizes insights from the previous chapter and (2) conceptual models of structural readiness. A brief review then follows of related, global developments to provide broader context for the cases. The chapter concludes with a preview of the transitions that will be discussed in depth in subsequent chapters. This book draws on my research of four national energy system transitions covering the period since 1970. I selected a timeframe that reflected a common context of international events which preceded as well as followed the oil shocks of 1973 and 1979. Such framing allowed me to trace policy and technology learning over multiple decades for different cases. I completed field work for this project primarily between 2010 and 2012, with updates continuing through to the time this book went to press. I selected cases from more than 100 countries in the International Energy Agency (IEA) databases. The ones that I chose represented countries which demonstrated an increase of 100% or more in domestic production of a specific, low carbon energy and the displacement of at least 15 percentage points in the energy mix by this same, low carbon energy relative to traditional fuels for the country and sector of relevance. I utilized adoption and displacement metrics to consider both absolute and relative changes. Final cases reflect a diversity of energy types and, to some extent, differences in the socio-economic and geographic attributes of the countries. The technologies represent some of the more economically-competitive substitutes for fossil fuels. It’s important to emphasize that the number of cases was neither exhaustive nor fully representative. Instead, the cases reflect an illustrative group of newer, low carbon energy technologies for in depth evaluation. Each of the cases shares certain, basic similarities. These include a national energy system comprised of actors, inputs, and outputs with systemic architecture connecting the constituent parts in a complex network of energy-centered flows over time—including extraction, production, sale, delivery, regulation, and consumption.

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Reviewing Usage, Potentials, and Limitations of Renewable Energy Sources

Energies ◽

10.3390/en13112906 ◽

2020 ◽

Vol 13 (11) ◽

pp. 2906 ◽

Cited By ~ 4

Author(s):

George E. Halkos ◽

Eleni-Christina Gkampoura

Keyword(s):

Climate Change ◽

Energy Source ◽

Renewable Energy ◽

Energy Demand ◽

Renewable Energy Sources ◽

International Energy Agency ◽

High Energy ◽

Energy Sources ◽

Energy Agency ◽

Address Climate Change

The world’s ever-increasing population, combined with economic and technological growth and a new, modern way of life, has led to high energy demand and consumption. Fossil fuels have been the main energy source for many years, but their use has many negative impacts on the environment. This has made the transition to renewable energy sources necessary in order to address climate change and meet the 1.5 °C goal. This paper is a review of the different types of renewables, their potentials and limitations, and their connection to climate change, economic growth, and human health. It also examines consumers’ willingness to pay for renewables in different countries, based on the existing literature. IEA (International Energy Agency) data are analyzed, concerning renewables’ current use, the evolution of their usage, and forecasts about their future usage. Finally, policies and strategies are recommended in order to address climate change and fully integrate renewables as a sustainable energy source.

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Recent trends and issues in energy conservation technologies

Heritage and Sustainable Development, ISSN 2712-0554 ◽

10.37868/hsd.v1i1.9 ◽

2019 ◽

Vol 1 (1) ◽

pp. 33-40

Author(s):

Ömer Faruk Ulusoy ◽

Erkan Pektaş

Keyword(s):

Energy Efficiency ◽

Renewable Energy ◽

Energy Consumption ◽

Energy Demand ◽

Industrial Revolution ◽

Renewable Energy Sources ◽

International Energy Agency ◽

Advanced Technology ◽

Energy Agency ◽

The World

Energy efficiency is a set of measures to prevent the loss of energy in gas, steam, air and electricity, to reduce energy demand by recycling and evaluating various wastes, or to reduce production by advanced technology, more efficient energy resources, advanced industrial processes, and energy recovery. The International Energy Agency announced that world energy consumption increased by 45% since 1980 and would be 70% higher by 2030 [1]. The energy policy of the future will be on saving, energy efficiency and renewable energy trilogy. Today, with the industrial revolution, the environmental problems and the damages caused by the world we live in today have reached the dimensions that threaten human health and ecological balance. Considering that the energy consumed in the world is in buildings, every measure that reduces energy consumption is very important in terms of improving life conditions. For this purpose, the importance of renewable energy sources in the design of energy architecture principles in energy efficiency and sustainable environments is stated.

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Techno-Economic Analysis of a Novel Hydrogen-Based Hybrid Renewable Energy System for Both Grid-Tied and Off-Grid Power Supply in Japan: The Case of Fukushima Prefecture

Applied Sciences ◽

10.3390/app10124061 ◽

2020 ◽

Vol 10 (12) ◽

pp. 4061 ◽

Cited By ~ 3

Author(s):

Naoto Takatsu ◽

Hooman Farzaneh

Keyword(s):

Renewable Energy ◽

Energy Demand ◽

Renewable Energy Sources ◽

Economic Assessment ◽

Energy System ◽

Modeling Framework ◽

Integrated Simulation ◽

Hybrid Renewable Energy System ◽

Renewable Energy System ◽

Hybrid Renewable Energy

After the Great East Japan Earthquake, energy security and vulnerability have become critical issues facing the Japanese energy system. The integration of renewable energy sources to meet specific regional energy demand is a promising scenario to overcome these challenges. To this aim, this paper proposes a novel hydrogen-based hybrid renewable energy system (HRES), in which hydrogen fuel can be produced using both the methods of solar electrolysis and supercritical water gasification (SCWG) of biomass feedstock. The produced hydrogen is considered to function as an energy storage medium by storing renewable energy until the fuel cell converts it to electricity. The proposed HRES is used to meet the electricity demand load requirements for a typical household in a selected residential area located in Shinchi-machi in Fukuoka prefecture, Japan. The techno-economic assessment of deploying the proposed systems was conducted, using an integrated simulation-optimization modeling framework, considering two scenarios: (1) minimization of the total cost of the system in an off-grid mode and (2) maximization of the total profit obtained from using renewable electricity and selling surplus solar electricity to the grid, considering the feed-in-tariff (FiT) scheme in a grid-tied mode. As indicated by the model results, the proposed HRES can generate about 47.3 MWh of electricity in all scenarios, which is needed to meet the external load requirement in the selected study area. The levelized cost of energy (LCOE) of the system in scenarios 1 and 2 was estimated at 55.92 JPY/kWh and 56.47 JPY/kWh, respectively.

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Optimal Planning and Operation of a Residential Energy Community under Shared Electricity Incentives

Energies ◽

10.3390/en14082045 ◽

2021 ◽

Vol 14 (8) ◽

pp. 2045

Author(s):

Pierpaolo Garavaso ◽

Fabio Bignucolo ◽

Jacopo Vivian ◽

Giulia Alessio ◽

Michele De Carli

Keyword(s):

Renewable Energy ◽

Power Distribution ◽

Energy Demand ◽

Renewable Energy Sources ◽

Energy System ◽

Distribution Networks ◽

Building Envelope ◽

Net Energy ◽

Technical Equipment ◽

Optimal Planning

Energy communities (ECs) are becoming increasingly common entities in power distribution networks. To promote local consumption of renewable energy sources, governments are supporting members of ECs with strong incentives on shared electricity. This policy encourages investments in the residential sector for building retrofit interventions and technical equipment renovations. In this paper, a general EC is modeled as an energy hub, which is deemed as a multi-energy system where different energy carriers are converted or stored to meet the building energy needs. Following the standardized matrix modeling approach, this paper introduces a novel methodology that aims at jointly identifying both optimal investments (planning) and optimal management strategies (operation) to supply the EC’s energy demand in the most convenient way under the current economic framework and policies. Optimal planning and operating results of five refurbishment cases for a real multi-family building are found and discussed, both in terms of overall cost and environmental impact. Simulation results verify that investing in building thermal efficiency leads to progressive electrification of end uses. It is demonstrated that the combination of improvements on building envelope thermal performances, photovoltaic (PV) generation, and heat pump results to be the most convenient refurbishment investment, allowing a 28% overall cost reduction compared to the benchmark scenario. Furthermore, incentives on shared electricity prove to stimulate higher renewable energy source (RES) penetration, reaching a significant reduction of emissions due to decreased net energy import.

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Primary Energy System Chain Security Under the Energy Transition

10.2118/204893-ms ◽

2021 ◽

Author(s):

Osamah Alsayegh

Keyword(s):

Electric Vehicles ◽

Energy Demand ◽

Oil And Gas ◽

Supply And Demand ◽

Energy Transition ◽

System Security ◽

Energy System ◽

Primary Energy ◽

Low Carbon ◽

Low Carbon Energy

Abstract This paper examines the energy transition consequences on the oil and gas energy system chain as it propagates from net importing through the transit to the net exporting countries (or regions). The fundamental energy system security concerns of importing, transit, and exporting regions are analyzed under the low carbon energy transition dynamics. The analysis is evidence-based on diversification of energy sources, energy supply and demand evolution, and energy demand management development. The analysis results imply that the energy system is going through technological and logistical reallocation of primary energy. The manifestation of such reallocation includes an increase in electrification, the rise of energy carrier options, and clean technologies. Under healthy and normal global economic growth, the reallocation mentioned above would have a mild effect on curbing the oil and gas primary energy demands growth. A case study concerning electric vehicles, which is part of the energy transition aspect, is presented to assess its impact on the energy system, precisely on the fossil fuel demand. Results show that electric vehicles are indirectly fueled, mainly from fossil-fired power stations through electric grids. Moreover, oil byproducts use in the electric vehicle industry confirms the reallocation of the energy system components' roles. The paper's contribution to the literature is the portrayal of the energy system security state under the low carbon energy transition. The significance of this representation is to shed light on the concerns of the net exporting, transit, and net importing regions under such evolution. Subsequently, it facilitates the development of measures toward mitigating world tensions and conflicts, enhancing the global socio-economic wellbeing, and preventing corruption.

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Analysis of Energy System in Norway with Focus on Energy Consumption Prediction

Management of Sustainable Development ◽

10.1515/msd-2017-0008 ◽

2017 ◽

Vol 9 (1) ◽

pp. 5-14 ◽

Cited By ~ 2

Author(s):

Maryam Hamlehdar ◽

Alireza Aslani

Keyword(s):

Energy Consumption ◽

Energy Demand ◽

Fossil Fuels ◽

Renewable Energy Sources ◽

Electricity Consumption ◽

Energy System ◽

High Energy ◽

Regression Result ◽

Industry Growth ◽

The Status

Abstract Today, the fossil fuels have dominant share of energy supply in order to respond to the high energy demand in the world. Norway is one of the countries with rich sources of fossil fuels and renewable energy sources. The current work is to investigate on the status of energy demand in Norway. First, energy and electricity consumption in various sectors, including industrial, residential are calculated. Then, energy demand in Norway is forecasted by using available tools. After that, the relationship between energy consumption in Norway with Basic economics parameters such as GDP, population and industry growth rate has determined by using linear regression model. Finally, the regression result shows a low correlation between variables.

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Passive solar systems for buildings: performance indicators analysis and guidelines for the design

E3S Web of Conferences ◽

10.1051/e3sconf/202019702008 ◽

2020 ◽

Vol 197 ◽

pp. 02008

Author(s):

Giacomo Cillari ◽

Fabio Fantozzi ◽

Alessandro Franco

Keyword(s):

Performance Indicators ◽

Energy Demand ◽

Evaluation Method ◽

International Energy Agency ◽

Objective Evaluation ◽

Design Guidelines ◽

Design Strategies ◽

Energy Agency ◽

Solar Systems ◽

Passive Solar

Data from the International Energy Agency confirm that in a zero-energy perspective the integration of solar systems in buildings is essential. The development of passive solar strategies has suffered the lack of standard performance indicators and design guidelines. The aim of this paper is to provide a critical analysis of the main passive solar design strategies based on their classification, performance evaluation and selection methods, with a focus on integrability. Climate and latitude affect the amount of incident solar radiation and the heat losses, while integrability mainly depends on the building structure. For existing buildings, shading and direct systems represent the easiest and most effective passive strategies, while building orientation and shape are limited to new constructions: proper design can reduce building energy demand around 40%. Commercial buildings prefer direct use systems while massive ones with integrated heat storage are more suitable for family houses. A proper selection must consider the energy and economic balance of different building services involved: a multi-objective evaluation method represents the most valid tool to determine the overall performance of passive solar strategies.

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Renewable and Sustainable Energy Transitions for Countries with Different Climates and Renewable Energy Sources Potentials

Energies ◽

10.3390/en11123523 ◽

2018 ◽

Vol 11 (12) ◽

pp. 3523 ◽

Cited By ~ 6

Author(s):

Haichao Wang ◽

Giulia Di Pietro ◽

Xiaozhou Wu ◽

Risto Lahdelma ◽

Vittorio Verda ◽

...

Keyword(s):

Renewable Energy ◽

Sustainable Energy ◽

Renewable Energy Sources ◽

Energy System ◽

Energy Sources ◽

Climate Conditions ◽

Energy System Model ◽

Cross Border ◽

Energy Transitions ◽

The Future

Renewable energy sources (RES) are playing an increasingly important role in energy markets around the world. It is necessary to evaluate the benefits from a higher level of RES integration with respect to a more active cross-border transmission system. In particular, this paper focuses on the sustainable energy transitions for Finland and Italy, since they have two extreme climate conditions in Europe and quite different profiles in terms of energy production and demand. We developed a comprehensive energy system model using EnergyPLAN with hourly resolution for a reference year for both countries. The models include electricity, heat and transportation sectors. According to the current base models, new scenarios reflecting an RES increase in total fuel consumption have been proposed. The future shares of renewables are based on each nation’s potential. The outcomes of the new scenarios support the future national plans, showing how decarburization in an energy system can occur in relation to the European Roadmap 2030 and 2050. In addition, possible power transmission between Italy and Finland were investigated according to the vision of an integrated European energy system with more efficient cross-border activities.

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How might controlled fusion fit into the emerging low-carbon energy system of the mid-twenty-first century?

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2020.0009 ◽

2020 ◽

Vol 378 (2184) ◽

pp. 20200009

Author(s):

G. R. Tynan ◽

A. Abdulla

Keyword(s):

Energy Demand ◽

Fusion Energy ◽

Energy System ◽

First Century ◽

Inertial Confinement ◽

Low Carbon ◽

Capital Costs ◽

Controlled Fusion ◽

Twenty First Century ◽

Low Carbon Energy

We examine the characteristics that fusion-based generation technologies will need to have if they are to compete in the emerging low-carbon energy system of the mid-twenty-first century. It is likely that the majority of future electric energy demand will be provided by the lowest marginal cost energy technology—which in many regions will be stochastically varying renewable solar and wind electric generation coupled to systems that provide up to a few days of energy storage. Firm low-carbon or zero-carbon resources based on gas-fired turbines with carbon capture, advanced fission reactors, hydroelectric and perhaps engineered geothermal systems will then be used to provide the balance of load in a highly dynamic system operating in competitive markets governed by merit-order pricing mechanisms that select the lowest-cost supplies to meet demand. These firm sources will have overnight capital costs in the range of a few $/Watt, be capable of cycling down to a fraction of their maximum power output, operate profitably at low utilization fraction, and have a suitable unit size of order 100 MW e . If controlled fusion using either magnetic confinement or inertial confinement approaches is to have any chance of providing a material contribution to future electrical energy needs, it must demonstrate these key qualities and at the same time prove robust safety characteristics that avoid the perceived dread risk that plagues nuclear fission power, avoid the generation of long-lived radioactive waste and demonstrate highly reliable operations. This article is part of a discussion meeting issue ‘Prospects for high gain inertial fusion energy (part 1)’.

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