Reprint

100% Renewable Energy Transition

Pathways and Implementation

Edited by
January 2020
356 pages
  • ISBN978-3-03928-034-6 (Paperback)
  • ISBN978-3-03928-035-3 (PDF)

This is a Reprint of the Special Issue 100% Renewable Energy Transition: Pathways and Implementation that was published in

Chemistry & Materials Science
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary

Energy markets are already undergoing considerable transitions to accommodate new (renewable) energy forms, new (decentral) energy players, and new system requirements, e.g. flexibility and resilience. Traditional energy markets for fossil fuels are therefore under pressure, while not-yet-mature (renewable) energy markets are emerging. As a consequence, investments in large-scale and capital intensive (traditional) energy production projects are surrounded by high uncertainty, and are difficult to hedge by private entities. Traditional energy production companies are transforming into energy service suppliers and companies aggregating numerous potential market players are emerging, while regulation and system management are playing an increasing role. To address these increasing uncertainties and complexities, economic analysis, forecasting, modeling and investment assessment require fresh approaches and views. Novel research is thus required to simulate multiple actor interplays and idiosyncratic behavior. The required approaches cannot deal only with energy supply, but need to include active demand and cover systemic aspects. Energy market transitions challenge policy-making. Market coordination failure, the removal of barriers hindering restructuring and the combination of market signals with command-and-control policy measures are some of the new aims of policies.The aim of this Special Issue is to collect research papers that address the above issues using novel methods from any adequate perspective, including economic analysis, modeling of systems, behavioral forecasting, and policy assessment.The issue will include, but is not be limited to:

  • Local control schemes and algorithms for distributed generation systems
  • Centralized and decentralized sustainable energy management strategies
  • Communication architectures, protocols and properties of practical applications
  • Topologies of distributed generation systems improving flexibility, efficiency and power quality
  • Practical issues in the control design and implementation of distributed generation systems
  • Energy transition studies for optimized pathway options aiming for high levels of sustainability
Format
  • Paperback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
energy system modelling; storage solutions; 100% renewable energy; Åland; vehicle-to-grid; power-to-gas; blockchain; community; energy market; electric vehicle; Demand Response; gamification; microgeneration; renewable energy; energy system modeling; decarbonization; global energy system model (GENeSYS-MOD); renewables; India; energy transformation; energy transition; sector coupling; microgrid; microgrid by design; energy community; net metering; prosumer; regulation; resilience; immunity; Solid State Transformer; electrostatic-driven inertia; variable renewable energy sources; wind power; solar energy; Germany; pumped hydro storage; system-friendly renewables; energy storage; ship’s electrical power system; dynamic positioning; blackout prevention; maritime transportation; energy system optimisation; carbon dioxide reduction; renewable energy; sector-coupling; open energy modelling; market value; decarbonization; energy system modeling; GENeSYS-MOD; renewables; energy policy; energy transformation; Energiewende; European electricity system; interconnector capacities; delayed grid expansion; electricity market modeling; decarbonization; renewable integration; renewable transition; numeric modelling; Mexico; climate policies; energy transition; energy policy; GENeSYS-MOD; island energy system transition; 100% RE pathways; RE integration; smart grid technologies; energy sector integration; smart energy system; Samsø; Orkney; Madeira; transport sector; transportation demand; final energy demand; road; rail; marine; aviation; levelized cost of mobility; greenhouse gas emissions; electrification; agent-based modelling; flexibility; renewable energy; electricity markets