LEADER 06128nam  2201345z- 450 
001 9910372782303321
005 20210211
010   $a3-03928-035-X
035   $a(CKB)4100000010163801
035   $a(oapen)https://directory.doabooks.org/handle/20.500.12854/39842
035   $a(oapen)doab39842
035   $a(EXLCZ)994100000010163801
100   $a20202102d2020      |y         0
101 0 $aeng
135   $aurmn|---annan
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 00$a100% Renewable Energy Transition: Pathways and Implementation
210   $cMDPI - Multidisciplinary Digital Publishing Institute$d2020
215   $a1 online resource (356 p.)
311 08$a3-03928-034-1 
330   $aEnergy 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
517   $a100% Renewable Energy Transition
606   $aHistory of engineering and technology$2bicssc
610   $a100% RE pathways
610   $a100% renewable energy
610   $aagent-based modelling
610   $aA?land
610   $aaviation
610   $ablackout prevention
610   $ablockchain
610   $acarbon dioxide reduction
610   $aclimate policies
610   $acommunity
610   $adecarbonization
610   $adelayed grid expansion
610   $aDemand Response
610   $adynamic positioning
610   $aelectric vehicle
610   $aelectricity market modeling
610   $aelectricity markets
610   $aelectrification
610   $aelectrostatic-driven inertia
610   $aEnergiewende
610   $aenergy community
610   $aenergy market
610   $aenergy policy
610   $aenergy sector integration
610   $aenergy storage
610   $aenergy system modeling
610   $aenergy system modelling
610   $aenergy system optimisation
610   $aenergy transformation
610   $aenergy transition
610   $aEuropean electricity system
610   $afinal energy demand
610   $aflexibility
610   $agamification
610   $aGENeSYS-MOD
610   $aGermany
610   $aglobal energy system model (GENeSYS-MOD)
610   $agreenhouse gas emissions
610   $aimmunity
610   $aIndia
610   $ainterconnector capacities
610   $aisland energy system transition
610   $alevelized cost of mobility
610   $aMadeira
610   $amarine
610   $amaritime transportation
610   $amarket value
610   $aMexico
610   $amicrogeneration
610   $amicrogrid
610   $amicrogrid by design
610   $anet metering
610   $anumeric modelling
610   $aopen energy modelling
610   $aOrkney
610   $apower-to-gas
610   $aprosumer
610   $apumped hydro storage
610   $arail
610   $aRE integration
610   $aregulation
610   $arenewable energy
610   $arenewable integration
610   $arenewable transition
610   $arenewables
610   $aresilience
610   $aroad
610   $aSamsų
610   $asector coupling
610   $asector-coupling
610   $aship's electrical power system
610   $asmart energy system
610   $asmart grid technologies
610   $asolar energy
610   $aSolid State Transformer
610   $astorage solutions
610   $asystem-friendly renewables
610   $atransport sector
610   $atransportation demand
610   $avariable renewable energy sources
610   $avehicle-to-grid
610   $awind power
615  7$aHistory of engineering and technology
700   $aBreyer$b Christian$4auth$01302963
702   $aOei$b Pao-Yu$4auth
702   $aKemfert$b Claudia$4auth
906   $aBOOK
912   $a9910372782303321
996   $a100% Renewable Energy Transition: Pathways and Implementation$93026778
997   $aUNINA