Sustainable Energy Systems

Original-Vortrag: siehe unten, Anmerkungen etc. Hans F Hoffmann

Systèmes énergétiques durables

Ecole Normale Supérieure Paris, 17 décembre 2002

Domenico Rossetti di Valdalbero

Commission Européenne, DG Recherche Tel.: +32-2-296.28.11 Fax: +32-2-299.49.91

E-mail: [email protected]

Sustainable Energy Systems

EC 6

th

FRAMEWORK PROGRAMME

Focusing and integrating research 1 Genomics and biotechnology for health

• Advanced genomics and applications for health • Combatting major diseases

2 Information Society technologies 3 Nanotechnologies and nano-sciences, knowledge-base multifunctional materials, new production processes and devices 4 Aeronautics and space 5 Food quality and safety 6 Sustainable development, global change and ecosystems

•

Sustainable energy systems

• Sustainable surface transports • Global change and ecosystems

7 Citizens and governance in a knowledge-based society 8 Specific activities covering a wider field of research Budget (MEuro) 2 255

1 100 1 155

3 625 1 300 1 075 685 2 120

810

610 700

225 1 300 Total 13 345 Sustainable Energy Systems

FP6 AS A TOOL FOR THE EUROPEAN RESEARCH AREA



Concentration on a limited number of priorities



Networking of research teams and projects



Creation of a genuine European added value



Structuring effect linking policies and schemes of

 national and regional authorities  other European actors 

Use mainly the new instruments (Integrated Projects and Networks of Excellence) Sustainable Energy Systems

SUSTAINABLE DEVELOPMENT, GLOBAL CHANGE AND ECOSYSTEMS (PRIORITY 6)



Sustainable energy systems (810 M €)



Short and medium term impact (DG TREN)



Medium and long term impact (DG RTD)



Sustainable surface transport (610 M €)



Global change and ecosystems (700 M €) Sustainable Energy Systems

DRIVING FORCES

 

The Lisbon strategy “for the EU to become the most competitive knowledge based economy of the world” and the Gothenburg conclusions on the EU strategy for Sustainable Development Communications towards the European Research Area and more specifically …



Green Paper

“Towards a European Strategy for the security of energy supply”

 

White Paper

“European Transport Policy for 2010: Time to decide”

The EC 6 th Environment Action Programme

“Environment 2010: our future, our choice”



Kyoto and Montreal Protocols, UN Conventions on Biodiversity and Desertification; Johannesburg Conclusions Sustainable Energy Systems

OBJECTIVES



Promoting clean, safe and affordable energy



Reducing greenhouse gases and pollutant emissions



Ensuring security of energy supply



Meeting the evolving energy demand



Increasing the share of renewable energy sources



Improving energy efficiency, industrial competitiveness and quality of life Sustainable Energy Systems

EXPRESSIONS OF INTEREST

 

more than 11.700 submitted overall more than 2.800 for Priority 6

  

775 for Energy (200 for Nuclear)

480 for Transport 1.400 for Global Change

  

15-20 % are mature 15% from Associated States IP/NoE ratio: 2/1

Sustainable Energy Systems

INSTRUMENTS



Integrated Projects (IP)



Networks of Excellence (NoE)



Specific Targeted Research Projects (STREP)



Co-ordination Actions (CA)



Specific Support Actions (SSA)

Sustainable Energy Systems

SHORT AND MEDIUM-TERM RESEARCH ACTIONS (405 M€)



Clean energy, in particular renewables

 Cost effective supply  Large scale integration 

Energy savings and energy efficiency

 Eco-buildings  Polygeneration 

Alternative motor fuels Sustainable Energy Systems

RENEWABLE ENERGIES (2003.SM)

IP & NoE STREP

 

Large innovative wind turbines, components and design tools Low cost photovoltaic modules with integrated dc/ac inverters than can feed power directly into the grid Large scale integration of renewable energy into energy supplies CA and SSA to prepare CONCERTO

ca: coord. act; ssa: spec.sup. act.

Sustainable Energy Systems



Combinations of biomass and wastes with fossil fuels



Innovative wind turbines



Transfer to industrial scale of a new generation of PV technologies



Geothermal energy

LARGE-SCALE INTEGRATION OF RES (2004.SM)

STREP IP



CONCERTO

IPs addressing the large scale

integration of RES

into energy supplies together with

eco buildings

and

polygeneration Cost Effective Supply: not opened

RES: renewable energy systems

Sustainable Energy Systems



RES electricity



Medium and low temperature RES heating and cooling



Polygeneration



Liquid and gaseous biofuels

ENERGY SAVINGS AND EFFICIENCY (2003.SM)

IP & NoE STREP



High performance eco- buildings Polygeneration:

Not opened 

Architecture for low-energy demand buildings



Integration of renewable & energy efficiency in buildings



Low energy construction and/or retrofitting materials



Innovative building management systems (BMS) Sustainable Energy Systems

IP

ENERGY SAVINGS AND EFFICIENCY (2004.SM)

STREP



CONCERTO

IPs addressing the large scale

integration of RES

into energy supplies together with

eco-buildings

and

polygeneration Proposals for only eco buildings or for only polygeneration will not be considered in this call.

Sustainable Energy Systems

ALTERNATIVE MOTOR FUELS

IP

(2003.SM)

STREP



Bio-fuels and/or hydrogen The IP should address in an holistic manner the whole alternative fuels chain, the so-called "well to wheel" approach.



Integration into the transport system



Demonstration of production, storage and distribution from RES



Demonstration of new ways of using alternative fuels



Strategies and tools to monitor and stimulate market demand



Assessment and monitoring of research activities Sustainable Energy Systems

ALTERNATIVE MOTOR FUELS

IP only

(2004.SM)

STREP



CIVITAS II

.

A joint initiative with sustainable surface transport Sustainable Energy Systems

MEDIUM AND LONG-TERM RESEARCH ACTIONS (405 M€)



Fuel cells, including their applications



New technologies for energy carriers, particularly H 2



New and advanced concepts in renewable energy technologies



Capture and sequestration of CO 2



Socio-economic tools and concepts for energy strategy Sustainable Energy Systems

FUEL CELLS (2003.ML)

IP & NoE



Systems for DG, combined heat/cold and power and mobile applications from a few kW to a few MW.



Solid polymer fuel cell for stationary and transport applications



Materials, processes, components and systems for proton exchange membrane and direct methanol fuel cells STREP



Fuel cell systems for small portable applications



Advanced computational models and simulation tools for fuel cells Sustainable Energy Systems

HYDROGEN (2003.ML)

IP & NoE STREP



Centralised and decentralised hydrogen production and purification from fossil, RES, and other



Hydrogen storage and infrastructure



Preparing for hydrogen as an energy carrier in energy systems

  

Safety of hydrogen technologies and harmonisation of testing procedures Sustainable Energy Systems Unconventional routes for hydrogen production Components and systems for specific hydrogen safety critical functions

IP & NoE

ELECTRICITY (2003.ML)

STREP



New demand driven solutions for large scale implementation of distributed energy resources in Europe



Novel concepts and advanced components for power networks with high DER penetration



Advanced energy storage systems for RES



Transmission systems



Energy storage for grid connected applications



High temperature superconductors devices Sustainable Energy Systems

IP & NoE

PHOTOVOLTAICS (2003.ML)

STREP



Thin-film PV technologies with higher efficiency / cost ratio



Cristalline Si modules costing below 1 €/Wp



High efficiency PV through better utilisation of the solar spectrum



Organic solar cells



PV concentration



Innovative concepts for PV in buildings



MW-size PV plants Sustainable Energy Systems

BIOMASS AND BIOENERGY (2003.ML)

IP & NoE STREP



Biofuel production from ligno-cellulosic feedstock



Production of hydrogen rich gas using multiple biomass feedstock including biomass residues/wastes



Overcoming barriers to the development of bioenergy production systems



Environmentally friendly biomass combustion technologies



Biofuels for fuel cells



Energy from bio-residues and energy crops Sustainable Energy Systems

OTHER RENEWABLES (2003.ML)

IP & NoE STREP



Wind - new and improved concepts



Ocean (tidal and wave) energy



Concentrated solar thermal



Geothermal energy enhanced geothermal systems Sustainable Energy Systems

CO

2

CAPTURE & SEQUESTRATION (2003.ML)

IP & NoE STREP



Pre-combustion capture technologies for CO2



Post-combustion capture technologies for CO2



CO2 capture and geological sequestration as a viable option for CO2 mitigation



Chemical/ mineral sequestration of CO2



Transport of CO2



CO/H2 and/or CO2/H2 separation in pre combustion capture Sustainable Energy Systems

SOCIO-ECONOMIC (2003.ML)

IP STREP



Quantification of energy externalities.



Social issues related to implementation of medium and long term energy technologies



Quantitative and qualitative forecasting methods Sustainable Energy Systems

EURATOM 6

th

FP

1 Management of radioactive waste 2 Controlled thermonuclear fusion 3 Radiation protection 4 Other activities 5 Activities of the Joint Research Center Total

(*) including EUR 200 million for participation in ITER

Sustainable Energy Systems Budget (M €) 90 750 (*) 50 50 290 1 230

INDICATIVE CALL ROADMAP 2003

Deadlines

Budget SM Budget ML

March 2003

82 M € 198 M €

65% for IP/NOE

Dec 2003

107 M € 4 M €

SSA

65% for IP

See call text for details

Sustainable Energy Systems

STAYING INFORMED



CORDIS:

http://www.cordis.lu/rtd2002/



EUROPA:

http://www.europa.eu.int/comm/dgs/research/index_en.html



DG Research energy web site:

http://europa.eu.int/comm/research/energy/index_en.html



DG Energy and Transport web site:

http://europa.eu.int/comm/energy/index_en.html



External relations office



National contact points



EC officials Sustainable Energy Systems

CONCLUSIONS



FP6 or a new approach : involve new participants; facilitate contacts between initiatives and identify overlaps, interactions and synergies



Consider always the overall policy context (ERA, Sustainable Development, Security of Energy Supply) and address related objectives



Focus on the topics/issues for which the call is inviting proposals



High ambitions of new instruments (complex, challenging…). Give yourselves the resources to meet the challenge Sustainable Energy Systems

EU Energy Research

WETO

: Business as usual, technical change as usual World energy demand: 1.8% increase/y ; EU: 0.4%; fossil fuels ~90% of total energy supply in 2030; oil 34%, coal 28%, gas 25%; nuclear&renewable <20% in EU In 2030,world CO2 emissions > twice 1990 EU ~18%, US~50% Sufficient oil reserves exist worldwide World oil production to increase by ~65% Oil price is to reach 35 €/bl in 2030

‘Energy, environment and sustainable development’ programme

My contact: European Commission Directorate-General for Research Domenico Rossetti di Valdalbero 2003; Directorate-General for Research EUR 20366 Hans F Hoffmann/ CERN-SG; Oct 2004

Further Assumptions and Conclusions

Hans F Hoffmann/ CERN-SG; Oct 2004

Literature

http://europa.eu.int/comm/research/energy/gp/gp_pu/article_1100_en.htm

The EU and Energy Research External Costs; Science and Technology for Sustainable Energy; European Energy Research; The European Research Area; Renewable Energy Newsletter; Vision for PV Technology; European Hydrogen and Fuel Cell Projects; European CO 2 Capture and Storage projects; European distributed energy resources projects; European Photovoltaics Projects report ; Clean, Safe and Efficient Energy for Europe; Renewable Energy Technologies and Kyoto Protocol Mechanisms; European Bio-Energy Projects, 1999-2002; New ERA for electricity in Europe; The Alternative Generation; CO 2 storage; Capture and Nuclear Fission and Radiation Protection Fusion Hans F Hoffmann/ CERN-SG; Oct 2004

Key message of European Strategy for Security of Energy Supply

Today the EU depends on imports for 50% of its energy needs and this may rise to 70% in 2020, if no action is taken.

No single energy option has the capacity on its own to fulfil all energy needs.

There is a need for diversity and this has to be reflected in policy agendas and research priorities.

Research has an essential role to play in enhancing and capitalising on the potential of all energy options, including nuclear fission and fusion.

European Energy Research Hans F Hoffmann/ CERN-SG; Oct 2004

THE EUROPEAN RESEARCH AREA for a sustainable energy future

Research is becoming increasingly complex, multi disciplinary and expensive to perform. The fragmented approach that has typified European research and development for many years is no longer adequate to meet today’s challenges.

This is as true for the field of sustainable energy systems as for any other area of research and development.

Advances in energy research involve long-term research programmes requiring European response.

resources beyond the capacity of any one Member State in Europe. The pressure of international competition necessitates an integrated The European Research Area Hans F Hoffmann/ CERN-SG; Oct 2004

Was tun??

Helmholtz Gemeinschaft:(„ mit aller Kraft-Energie für die Zukunft “??) 6 Zentren haben Energieforschung (DLR,FZJ,FZK,GFZ,HMI, IPP) Koordinierungsstelle: FZ-Jülich; Eisenbeiß Projekt mit HGF vorschlagen, zum Beispiel solar-thermisches Prototyp Kraftwerk im Norden Afrikas, in Zusammenarbeit mit Italien/ENNEA?

Teilnahme an geeignetem EU-Projekt?

Partnersuche: Wer sind die Europäischen Partner?

Welche Industrie ist wirklich an einem Prototyp interessiert?

WR: Energieversorgung sichern, Umweltbelastungen reduzieren, Energie wirtschaftlich und nachhaltig bereitstellen, Energie haushalterisch nutzen, Energieoptionen öffnen, Staatliche Forschungsförderung stärken, Industrielle Forschung muss stärker kooperieren, Forschung und ihre Förderung bündeln, sozial und geisteswissenschaftliche Forschung integrieren, Nachwuchs fördern Hans F Hoffmann/ CERN-SG; Oct 2004

CERN collaborates with the Universities of the world

732 722 4231 MS 30 100 50 50 1932 nMS 10 CERN: 20 Member States; 2400 staff- 500 fellows, associates; ~ 930 MCHF annual contributions 250 institutes in MS: 4500 scientists; 210 institutes in nMS: 2000 scientists

How do we collaborate: LHC Experiments

CERN LCG-the common Grid/Cyber-Infrastructure

LCG-2

Internet2 land speed record: ~6 Gb/s transfer>1Terabyte Caltech-CERN 4 National Labs 2800 CPUs

30 sites 3200 cpus

Grid3

CERN: Nobel and Millennium Price Winners

Carlo Rubbia, Simon van der Meer Georges Charpak Tim Berners Lee