extreme light infrastructure eli recommended to be on the esfri road map
TRANSCRIPT
Extreme Light InfrastructureELI
Recommended to be on the
ESFRI Road Map
ELICentered around an Exawatt class
Laser
Few kJ.~10fs, >1sh/mn)
Modular:
1) front end at 100Hz-kHz, 5fs-5J, PW level,
2) Last stage at the exawatt level@>1shot/mn
3) a0~102-104
ELI Scientific Program:Rests on Three Scientific Pillars
1)
• Ultra high Field Science: access to the ultra-relativistic regime, ELI will afford new investigations in particle physics, nuclear physics, gravitational physics, nonlinear field theory, ultrahigh-pressure physics, astrophysics and cosmology.
• Attosecond science: snap-shots in the attosecond scale of the electron dynamics in atoms, molecules, plasmas and solids.
• High Energy beam facility: ELI will provide ultra-short energetic particle (>10 GeV) and radiation (up to few MeV) beams produced from compact laser plasma accelerators.
Societal Benefits
• ELI will afford wide benefits to society ranging from improvement of oncology treatment, medical imaging, fast electronics and our understanding of aging nuclear reactor materials to development of new methods of nuclear waste processing.
Relativistics microelectronic devices
Plasma cavity
100 m1 m
RF cavity
ELI
Courtesy of W. Mori
Fundamental
Interaction
Ultra-Relativistic optics
Super hot plasma
Nuclear Physics
Astrophysics
General relativity
Ultra fast phenomena
NLQED
Relativistic
Engineering
ELIExtreme Light Infrastructure
Exawatt Laser
Secondary
Beam Sources
Electrons
Positron
ion
Muon
Neutrino
Neutrons
X rays
rays
accelerators
Synchr. Xfel
Attosecond optics
Rel. Microelectronic
Rel. Microphotonic
Nuclear treatement
Nuclear pharmacology
Hadron therapy
Radiotherapy
Material science
Electron beam energy and laser power evolution
1012
1013
1014
1015
1016
1017
Las
er P
ow
er (
W)
1
10
102
103
104
105
106
1930 1940 1950 1960 1970 1980 1990 2000 2010
« conventional » technology M
axim
ale
Ele
ctro
ns
En
erg
y (
MeV
)
Years
LULI
RAL LOA
LOA*LBNL
UCLA
ILE ¤
KEK
UCLA
ELI
ELI
*LBNL
*LUND
INFN, Frascati, March 7 (2006)
ELIParameter designs Laser Plasma Accelerators
ELI : > 100 GeV
40
13
4
1.3
Q(nC)
112042804702e151000120/120K
112491502e1630012/3.6k
11.240.28472e171001.2/120
1.1240.009152e18300.12/3.6
E(Gev)
a0L(m)W0 (μm)ne(cm-3)τ (fs)
P(PW)E(J)
Golp and UCLA Group
Extreme Light InfrastructureELI
A science integrator that will bring many frontiers of contemporary physics, i.e. relativistic plasma physics, particle physics, nuclear physics, gravitational physics, nonlinear field theory, ultrahigh pressure physics, and cosmology together.
ELI will provide a new generation of compact accelerators delivering ultra short (fs-as) and energetic particle and radiation beams for European scientists. ELI will work in close contact with synchrotron XFEL community.
ELI will also be an Extreme Light technology platform ready to reduce to practice the latest invention and discovery in relativistic engineering
ELI
Education and Training:
ELI will be the most sophisticated Optoelectronic Grand Instrument (Ultrashort short pulse, Ultra relativistic intensity, High repetition rate, wavefront correction, Coherent Addition of Beams) and will be a fertile ground for Education and Training.
Time line
2007 2008 2009 2010 2011 2012 2013 2014
10/20 PW @ 1shot/mn single beam
40/70 PW @ 1Hz single beam
400/700 PW @ 1Hz 10 beams
G.IV ELI budget summary over the first 10 years (in M€)
197,67,57,57,57,57,531,939,618,229,937,2Total/ year
52.57777774,83,61,40 ,7Operation and maintenance
costs
6.61.01.01.0 1.01.00,80,60,2Manpower forexploitation
7,51 ,51,51,51,51,5Manpower for laser/ beamline
1578Building
1162333132027Total equipment
202335 7EquipmentExp. beamlines
512130Equipment Laser (phase 2)
45101520EquipmentLaser (phase 1)
Total10987654321Years
ELI Participating Countries
• France• Germany• Spain• Italy• Greece• Lithuania• Austria
ELI Participants• 1LULI, CNRS-X, CEA, Université Paris XI, 91128
Palaiseau (France)• 2LOA, CNRS-ENSTA-X, 91761 Palaiseau
(France)• 3Johannes-Gutenberg-Universitat Mainz, D 55099
Mainz (Germany)• 4GSI, Planckstr.1 64291 Darmstadt (Germany)• 5LLR, CNRS-IN2P3-X, 91128 Palaiseau (France)• 6Thalès, STI, 92704 Colombes cedex (France)• 8General Physics Institute RAS, Moscow 119991
(Russia)• 9IESL (Heraklion) 71110, Crete (Greece)• 10Institut für Angewandte PM, D-85577 Neubiberg
(Germany)• 11IOTA, Bât 503, 91403 ORSAY Cedex (France)• 12CPO, Bat. 101, 91898 Orsay cedex (France)• 13FASTLITE Bâtiment 403 Campus de l'X 91128
Palaiseau (France)• 14LMU, Am Coulombwall 1, D-85748
Garching (Germany) • 15CENBG, CNRS, IN2P3, Université Bordeaux 1
(France)
• 16Max-Planck-Institut fuer Kernphysik, Heidelberg D-69117 (Germany)
• 17Heinrich-Heine-Universitaet Duesseldorf, D-40225 Duesseldorf
• 18MPQ, Max-Planck-Institut fur Quantenoptik, D-85748 Garching 19Imperial College, Imperial College London, SW7 2AZ London (U. K.)
• 20Dept. of Physics,Univ of Strathclyde, Glasgow G4 0NG (Scotland)
• 21Centre de Physique Theorique, CNRS-X, 91128 Palaiseau (France)
• 22Dipartimento di Fisica,Universita' di Pisa, 56100 Pisa (Italy)• 23LSI, CNRS-X, F-91128, Palaiseau (France)• 24Department of Quantum Electronics, LT-10222 Vilnius
(Lithuania)• 25LIXAM, CNRS-Université Paris XI, Bât 350, 91405 Orsay
(France)• 26Institut für Optik und Quantenelektronik, D07743 Jena
(Germany)• 27ESFR, 6, rue Jules Horowitz,BP 220, Grenoble 38043
(France)• 28Technische Universität Dresden, ITP, 01062 Dresden
(Germany)• 29CELIA, Universite Bordeaux 1, 33405 Talence cedex
(France)• 30Amolf FOM, Kruislaan 407, 1098 SJ Amsterdam (The
Netherlands)