| Energy (439) |  |
| Energy consumption (16) | |
| Energy efficiency (13) | |
| Energy production (13) | |
| Energy sector (4) | |
| Energy system (19) | |
| New energy (9) | |
| Sustainable energy (15) | |
| Energy (439) | |
| Energy consumption (16) | |
| Energy efficiency (13) | |
| Energy production (13) | |
| Energy sector (4) | |
| Energy system (19) | |
| New energy (9) | |
| Sustainable energy (15) | |
Des. 117 (Special B)( 1995) 2 10.15 C. Marchetti, N. Nakicenovic, The Dynamics of Energy systems and the Logistic Substitution Model, International Institute for Applied Systems analysis
and in the Nordic countries is carried out at VTT, namely the Nordic Energy Research Climate and Energy systems:
Demands for research were incorporated into strategy planning primarily through the energy systems'actors and industrial actors,
In the Nordic H2 Energy Foresight the major challenge was to create shared understandings on future hydrogen-based energy systems between different stakeholder groups representing five different countries.
Increasing push for greater efficiency and decarbonisation of the energy system because of the environmental and energy security concerns;
Another internationally relevant disruption of energy systems on the scale of a Chernobyl nuclear accident. These examples suggest that wild cards involve relatively high impact but somewhat low probability events and situations that carry a lot of conditionality.
climatic and energy systems change are on the top of respondents minds. The general area of health system developments and changes is also prominent.
Some of the striking discontinuities are shown in Table 5. Discontinuities with respect to fairly rapid shifts in energy systems,
At the more or less blurred borderlines, other systems (energy system, land-use patterns and economic system) are attached and interact.
The proposed approach is illustrated by means of a long-term policy-making case related to the transition of energy system toward sustainability.
Energy systems are complex, their development over time is dynamically complex, and many aspects related to these systems and their future developments are deeply uncertain.
a System Dynamics 50,51 model developed for exploring the dynamics of energy system transitions 3 is used in this study.
resulting in a dynamic adaptive policy that improves the extent towhich the energy system transits to a more sustainable functioning.
His applied interests include climate change/energy issues, public health and health policies, financial crisis and energy systems. His current research interests are adaptive policy making and the use of optimization in policy-making.
Applied interests include economic-financial crises, climate change and energy system transitions, and inter/national safety and security. 418 C. Hamarat et al./
but the most important methodological Box 1. Final priorities in the Research2015 catalogue 34 Energy, climate and the environment Energy systems of the future Future climate and climate adaption Competitive environment
Theme Budgets in millions of DKKS 2009 2010 Energy, climate and environment Energy systems of the future 190 455 Future climate and climate adaptation 43 0 Climate
T.,Carrillo Hermosilla, J.,Loikkanen, T. and van der Have, R. 2009) Governance of energy system transition:
Innovation policy roadmapping. 189 Eerola, A. and Loikkanen, T. 2009) Governance and Research of Nordic Energy system Transition-Summary Report of the Gorenest Project, VTT Research Notes 2505.
< Back - Next >
Overtext Web Module V3.0 Alpha
Copyright Semantic-Knowledge, 1994-2011