extreme light infrastucture (eli) science and technology ... · extreme light infrastucture (eli)...
TRANSCRIPT
Extreme Light Infrastucture (ELI)
Science and Technology at the ultra-intense Frontier
Bruno Le Garrec
On behalf of Georg Korn, Bedrich Rus and the ELI-Beamlines team
Institute of Physics v.v.i., Prague Czech Republic
SPIE Photonics West 2.2.2014
1
Outline
• What is ELI – Where are we coming from and where are we going
• ELI-Beamlines – In the Czech Republic
• Lasers – Technologies
• Experiments – Planned experiments and some we are involved in
• Beam transport and switchyard – Because beamlines should go to experimental areas
2
Extreme Light Infrastructure
3
Czech Republic
Prague
Hungary
Szeged Romania
Bucharest - Magurele
2007-2010 ELI Preparatory Phase project (13 countries)
Oct 1st, 2009 ELI-PP Steering Committee approves the conception of three
ELI pillars (Beamlines, Attosecond, Nuclear Physics)
Attosecond facility, ALPS
Beamlines facility
Attosecond XUV/X-ray physics
High-brightness sources of X-ray radiation & particles
Photonuclear facility , NP
Szeged
Magurele
Prague
Laser-induced nuclear physics
200 PW facility (?) Frontier physics by exawatt lasers
4
Structure of implementation of the ELI project
May 2010 ELI-Beamlines pre-approved for funding
Apr 2011 ELI-Beamlines funding approved by EC
Aug 2011 Funding (278 M€) signed by the Czech Rep’s Ministry of
Education, Sports and Youth
Dec 2012 Agreement from EC to deliver facility after 2015
European Regional Development Fund
(infrastructural funds)
May 2013 Facility Construction start
Sept 2015 Start of installation of laser systems
Dec 2015 Phase I completed: two laser units + support installed
2016-2017 Phase II: lasers & experiments installed
2018 Facility commissionning
ELI project background
5
ELI Beamlines location
6
7
Building http://www.eli-beams.eu/about/building/
• Site area 65,000 m2
• Building(s) 28,645 m2
• Building volume 170,000 m3
• Experimental building 16,500 m2
• Laboratories 4,500 m2
• Offices 4,400 m2
• Multifunction areas 2,300 m2
• Total estimated construction costs of €65M
• Foundation raft slab thickness 1m;
• 1.6m shielded reinforced concrete walls in the underground;
• Cellular reinforced concrete ceiling slab thickness 1.5m; span 20m
Lasers
Experiments
ELI Beamlines mission: fundamental & applied science
• Research Program 1: lasers generating rep‐rate ultra-short pulses and multi‐petawatt peak power
• Research Program 2: X‐ray sources driven by rep‐rate ultra-short laser pulses.
• Research Program 3: particle acceleration by lasers
• Research Program 4: applications in molecular, biomedical, and material sciences
• Research Program 5: laser plasma and high‐energy‐density physics
• Research Program 6: high‐field physics
8
9
WP 3 Lasers
WP 4.3 Beam Transport
WP 5 Secondary
Sources
WP 6 Experiments
ELI-Beamlines baseline
ELI- Beamlines baseline
• 4 beamlines “L1, L2, L3 and L4”
• L1 kHz rep-rate, 100 to 200 mJ, 20 fs
• L2 and L3 PW at 10 Hz, 20-30 J, 20-30 fs
• L4: 10 PW and high energy “kJ” beam, 1.5 kJ – 150 fs
• Beamlines based either on existing or newly developed technologies
• DPSSL and flashlamp pumped
• OPCPA, Ti: Sapphire and mixed glass technologies
• Thin disk (MPQ, MBI and Trumpf)
• Multi slabs ( Dipole – STFC, Mercury- LIFE- LLNL)
• Mixed glass (Texas PW laser, Apollon pump laser)
• Czech program for High Power Laser development “HILASE”
10
ELI- Beamlines baseline
• L1: DPSSL / ps pump for OPCPA
– Mostly developed and built at the Institute of Physics in Prague
• L2: DPSSL – Yb:YAG cryo-cooled multi slabs
– First step 10J/10Hz bought from STFC (Dipole type)
– Second step 100/10Hz bought by HILASE from STFC
• L3: DPSSL – Nd:Glass He cooled multi slabs (Mercury like)
– Contract with LLNS signed in September 2013
• L4: flashlamp – mixed glass (Apollon pump laser type)
– Tender in process, 2nd round
• J.T. Green et al, Monday 3rd, session 8, SPIE 8959-35
• R. Antipenkov et al, Monday 3rd, session 9, SPIE 8959-44
• J. Novak et al, Tuesday 4th, session 11, SPIE 8959-49
11
HiLASE http://www.hilase.cz/en/
• Research Program 1 (kW-class thin-disk laser)
– Milestone 1: 100 mJ @ 1 kHz, 1-2 ps 2013
– Milestone 2: 0.5 J @ 1 kHz, 1-2 ps 2014
– Milestone 4: 5 mJ @ 100 kHz, 1-2 ps 2014
– Milestone 3: ~1 J @ 1 kHz, 1-2 ps 2015
• Research Program 2 (cryo-cooled multislab laser)
– Milestone 1: 1-10 J @ 10 Hz, ns, 160 K 2014
– Milestone 2: 100 J @ 10 Hz, 2-3 ns, 160 K 2015
• Research Program 3 (Applications)
– Design and install processing chambers 2014
– Use RP-1 & RP-2 lasers for industrial application 2015
• P. Sikocinski et al, Monday session 6, SPIE 8959-26
• M. Chyla et al, Monday session 7, SPIE 8959-29
• Posters SPIE 8959-72, 73 & 75 12
13
ELI-Beamlines baseline
• kHz repetition rate laser using thin-disk pump
technology
• Oscillator and common front end producing
mutually synchronized seed pulses
• Capable to generate several seeds with
central wavelengths from 800 to 900 nm
• Picosecond OPCPA system for broadband
amplification
L1 Beamline
Front end
Pump laser(s)
Compressor chamber
OPCPA & mirror
compressor Diagnostics
14
L2 beamline: OPCPA
15
Yb:YAG amp head & pump diode lasers 10J / 10Hz Yb:YAG subsystem: STFC Front end, beam transport & cryo unit: ELI-Beamlines
High average power Ti:sapphire multipass amplifiers L3 pumped by Nd:glass operating at near-room-temperature
16
L3 PW-type beamlines
L4 Beamline
• Main beam energy (fundamental wavelength) >1.5 kJ
• Stretched pulse duration 0.5 to 3 ns
• Shot rate >1 per minute
• Compressed pulse peak power ≥10 PW
• Compressed pulse duration <150 fs direct compression,
• Nanosecond kJ pulses required for laser plasma experiments
• Spectral bandwidth for direct compression to ~150 fs (e- acceleration)
Upgrade option: OPCPA
10PW: mixed glass system Mixed glass technology: high energy & bandwidth equivalent to <130 fs FWHM *
* ELI - Extreme Light Infrastructure White Book: Science and Technology with Ultra-Intense Lasers edited by G. Mourou, G. Korn, W. Sandner and J. Collier (2011)
Nd:phosphate glass 1053.9 nm Nd:silicate glass 1061 nm Texas Petawatt laser:
185 J / 130 fs – scalable -> 1900 J /130 fs
• Straightforward choice for e- acceleration • The laser can be used as a pump of an OPCPA chain (Vulcan 10 PW solution)
18
Experiments
• Secondary sources and beamlines, applications based on intense laser plasma interaction and connected with it => High Harmonic Generation => X-rays => Particle acceleration (e, p, ions)
• Secondary effects of electron acceleration: X-rayBeam (compact laser driven X-FEL, betatron radiation,..)
• Plasma physics, Raman and Brillouin amplification schemes
19
ELI- Beamlines baseline
20
Secondary sources
Experimental Areas, Basement floor
21
E1: HHG, k-alpha,
3D3C imag. E2: Betatron
E3: Plasma Physics
Combinations with different lasers,
Backighters x-rays and protons, optical E4: ELIMAIA
Combination with backlighting, after
proton heating of samples
E5: LUX , HELL, HHG
OPA, Compton, Kalpha
Systems Engineering
Systems engineering at the facility level:
• Alignment (lasers to experiments)
• Diagnostics
• Beam Transport
• Control system – Linux & C++ & Python
– & Tango/EPICS
• Performance – Virtual Beamline Model
22
L2
L4 L1
L3
Conclusion
• => mid 2015 building ready
• http://www.eli-beams.eu/about/building/
• => end 2015 develop and buy most of the technology – two beamlines L1 , L2 available
– Beam transport, support technologies
• => 2016-2017: 4 beamlines, commissioning
• => 2018 starts experiments and toward a users’ facility
23