Coordinatore | STIFTUNG DEUTSCHES ELEKTRONEN-SYNCHROTRON DESY
Organization address
address: NOTKESTRASSE 85 contact info |
Nazionalità Coordinatore | Germany [DE] |
Totale costo | 8˙044˙597 € |
EC contributo | 5˙700˙000 € |
Programma | FP7-INFRASTRUCTURES
Specific Programme "Capacities": Research infrastructures |
Code Call | FP7-INFRASTRUCTURES-2007-1 |
Funding Scheme | CP-CSA-Infra |
Anno di inizio | 2008 |
Periodo (anno-mese-giorno) | 2008-04-01 - 2011-03-31 |
# | ||||
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1 |
STIFTUNG DEUTSCHES ELEKTRONEN-SYNCHROTRON DESY
Organization address
address: NOTKESTRASSE 85 contact info |
DE (HAMBURG) | coordinator | 0.00 |
2 |
ELETTRA - SINCROTRONE TRIESTE SCPA
Organization address
address: SS 14 KM 163.5 contact info |
IT (BASOVIZZA TRIESTE) | participant | 0.00 |
3 |
HELMHOLTZ-ZENTRUM BERLIN FUR MATERIALIEN UND ENERGIE GMBH
Organization address
address: Hahn-Meitner-Platz 1 contact info |
DE (BERLIN) | participant | 0.00 |
4 |
ISTITUTO NAZIONALE DI FISICA NUCLEARE
Organization address
address: Via Enrico Fermi 40 contact info |
IT (FRASCATI) | participant | 0.00 |
5 |
LUNDS UNIVERSITET
Organization address
address: Paradisgatan 5c contact info |
SE (LUND) | participant | 0.00 |
6 |
PAUL SCHERRER INSTITUT
Organization address
address: Villigen contact info |
CH (VILLIGEN PSI) | participant | 0.00 |
7 |
SCIENCE AND TECHNOLOGY FACILITIES COUNCIL
Organization address
address: Polaris House North Star Avenue contact info |
UK (SWINDON) | participant | 0.00 |
Esplora la "nuvola delle parole (Word Cloud) per avere un'idea di massima del progetto.
'The successful demonstration of single-pass free electron lasers (FEL) around the year 2000 triggered a number of research centres in Europe, the United States and Asia to initiate the construction of new research infrastructures. These projects are based on strong science cases put forward by interested research communities. The new FEL sources combine the wide and continuously tunable wavelength range of synchrotron radiation with ultra-short pulses and coherence of lasers, but at much higher peak and average power, offering completely new research opportunities in different areas of science for a large research community. Several European countries are supporting the construction of national FEL facilities which are now combining their forces and coordinating their activities to build and operate a distributed European facility, the IRUVX-FEL. This facility will be able to offer a suite of complementary sources and instrumentation that is unsurpassed in the world. The main objective of the IRUVX-FEL Preparatory Phase is the integration of the national FEL facilities into a distributed European FEL facility in order to fully exploit the complementary features and expertise of the individual member facilities and to maximise the benefits for both the member facilities and the users. This includes the agreement and implementation of structures and methods that allow efficient construction and operation of the IRUVX-FEL facility, and the preparation of critical technology ensuring that all member facilities will be exploited with highest efficiency. The access to this world-class facility will be facilitated by transparent and coordinated access policies and procedures agreed by the IRUVX-FEL consortium. The present proposal includes all the necessary preparatory work to build this consortium with the goal to offer world-class service in response to the needs formulated by the research community.'
A new laser facility will beam Europe into technological primacy, creating the 'flash camera' of the molecular world.
Lasers play an important role in research and technology, touching on many key fields from medical imaging to national defence. In particular, the free-electron laser (FEL), which is more versatile and more tuneable, has opened up a whole range of applications. About a decade ago, an even more advanced type of FEL was launched that is able to generate X-rays. Many research centres around the world flourished with this new discovery as they wanted to learn more about the new laser technology and apply it in different ways.
The 'Preparatory phase of the IRUVX-FEL consortium' (http://www.iruvx.eu/e20 (IRUVX-PP)) project worked on harnessing this power by preparing for a new European facility known as EuroFEL. This facility has been conceived to offer complementary sources and instrumentation that are unsurpassed in the world.
In this context, EuroFEL partners created a plan to integrate national FEL facilities into a distributed European facility. The plan was designed to fully exploit the complementary features and expertise of individual member facilities and maximise benefits for all involved. The endeavour includes implementation of structures and methods that promote the efficient construction and operation of the EuroFEL facility.
The consortium established policies to facilitate access to this state-of-the-art facility, offering world-class service in response to the needs of the research community. It reviewed and defined the core activities of the future EuroFEL and prepared comprehensive reports for establishing the joint facility. This included a detailed description of envisioned activities, mission, budget estimates, internal procedures and more.
In more scientific terms, the new FEL technology combines wide and continuously tuneable wavelength radiation with ultra-short pulses and the coherence of lasers, yielding much more power. It covers the terahertz, infrared, visible and ultraviolet spectrum up to hard X-rays, producing extremely short (femtosecond) flashes of light with unprecedented intensities at short wavelengths.
FELs are flash cameras for the molecular world, adding the femtosecond time scale to nanometre microscopy. This can be used to observe intricate phenomena and opens up new research opportunities in numerous scientific disciplines, from the physics of atoms, molecules and clusters to plasma physics, chemistry, nanosciences, materials and biomaterials.
Overall, preparations for the new facility have involved defining user needs and access, conducting workshops, finding the required human resources and networking with industry. Once the facility is completed, it will lead to the development of novel technologies and applications ranging from micro-electronics to energy.