1. Laser Plasma Accelerators: Principle & applications
LOA
Laser Plasma Accelerators:
Principle & applications
Victor Malka
Laboratoire d’Optique Appliquée
ENSTA-Ecole Polytechnique, CNRS
91761 Palaiseau, FRANCE
Partially supported by CARE/PHIN FP6 project
John Adams Insitute, Oxford UK, January 10, 2008

2. Acknowledgement SPL ELF Particle group Laser group J. Faure F. Burgy
LOA
Acknowledgement
SPL
ELF
Particle group
J. Faure
Y. Glinec
A. Lifschitz
C. Rechatin
Laser group
F. Burgy
B. Mercier
J.Ph. Rousseau
Collaborators
Pukhov, University of Dusseldorf, Germany
E. Lefebvre, CEA/DAM Ile-de-France, France
John Adams Insitute, Oxford UK, January 10, 2008

3. Summary Part 1 : Laser plasma accelerator : motivation
LOA
Summary
Part 1 : Laser plasma accelerator : motivation
Part 2 : Laser Plasma accelerator as injector : Production of monoenergetic electron beam
Part 3 : New scheme of injection : toward a stable, tuneable and quasi monoenergetic electron beam.
Part 4 : Applications
Part 5 :Conclusion and perspectives
John Adams Insitute, Oxford UK, January 10, 2008

4. Classical accelerator limitations
LOA
Classical accelerator limitations
E-field max ≈ few 10 MeV /meter (Breakdown)
R>Rmin Synchrotron radiation
Energy = Length = $$$
Circle road
LEP at CERN
PARIS ≈
27 km
31 km
New medium : the plasma
John Adams Insitute, Oxford UK, January 10, 2008

5. n E ~ w Why is a Plasma useful ?
LOA
Why is a Plasma useful ?
Superconducting RF-Cavities : Ez = 55 MV/m
Plasma is an Ionized Medium High Electric Fields e p z n E ~ w
John Adams Insitute, Oxford UK, January 10, 2008

6. n E ~ How to excite Relativistic Plasma waves? The laser wake field
LOA
How to excite Relativistic Plasma waves?
The laser wake field
Laser pulse
F≈-grad I
Electron density perturbation
Phase velocity vfepw=vglaser => close to c
Analogy with a boat
tlaser≈ Tp / 2
=>Short laser pulse e z n E ~
Are Relativistic Plasma waves efficient ?
Ez = 0.3 GV/m for 1 % Density Perturbation at 1017 cc-1
Ez = 300 GV/m for 100 % Density Perturbation at 1019 cc-1
Tajima and Dawson, PRL (1979)
Tajima&Dawson, PRL79
John Adams Insitute, Oxford UK, January 10, 2008

7. Analogy electron/surfer
LOA
Analogy electron/surfer t 1 t t 2 3
électron g
>
> g f
>
> 1 e
=> E
max
(MeV)­( d
n/n)(n c /n e )
=>L
deph. =( l
/2)(n
3/2 E
=2(
n/n) g f 2 mc L
Deph. = p
Analogy:
John Adams Insitute, Oxford UK, January 10, 2008

8. LOA
John Adams Insitute, Oxford UK, January 10, 2008

9. Classical accelerator limitations
Courtesy of W. Mori & L. da Silva
Plasma cavity
100 mm
1 m
RF cavity
LOA
John Adams Insitute, Oxford UK, January 10, 2008

10. Summary Part 1 : Laser plasma accelerator : motivation
LOA
Summary
Part 1 : Laser plasma accelerator : motivation
Part 2: Laser Plasma accelerator as injector : Production of electron beam
Part 3 : New scheme of injection : toward a stable, tuneable and quasi monoenergetic electron beam.
Part 4 : Applications
Part 5 :Conclusion and perspectives
John Adams Insitute, Oxford UK, January 10, 2008

11. Interaction chamber (inside)
LOA
Interaction chamber (inside)
Laser beam
electron beam
50 cm
John Adams Insitute, Oxford UK, January 10, 2008

12. Laser plasma injector Scheme of principle Experimental set up LOA
John Adams Insitute, Oxford UK, January 10, 2008

13. Spatial quality improvements
LOA
Spatial quality improvements
5.0 x 1019cm-3
3.0 x 1019cm-3
2.0 x 1019cm-3
1.0 x 1019cm-3
7.5 x 1018cm-3
6.0 x 1018cm-3
Divergence = 6 mrad
John Adams Insitute, Oxford UK, January 10, 2008

14. Recent results on e-beam : From Mono to maxwellian spectra
LOA
Recent results on e-beam :
From Mono to maxwellian spectra
Electron density scan
V. Malka, et al., PoP 2005
John Adams Insitute, Oxford UK, January 10, 2008

15. Energy distribution improvements:
LOA
Energy distribution improvements:
The Bubble regime
Charge in the peak : pC
Divergence = 6 mrad
Experiment
PIC
At LOA
J. Faure et al. Nature (2004)
John Adams Insitute, Oxford UK, January 10, 2008

16. Other results RAL & LBNL also to be published tomorrow in Nature 04
LOA
Other results RAL & LBNL
also to be published tomorrow in Nature 04
50 pC
300 pC
RAL & LBNL
John Adams Insitute, Oxford UK, January 10, 2008

17. S. Mangles et al., C. Geddes et al., J. Faure et al.,
LOA
S. Mangles et al., C. Geddes et al., J. Faure et al.,
in Nature 30 septembre 2004
John Adams Insitute, Oxford UK, January 10, 2008

18. Quasi-monoenergetic beams reported in the litterature
Article
Energy
dE/E
Charge Ne
Intensity
tL/Tp
Remark
Name
Lab
[MeV]
[%]
[pC]
[x1018
/cm 3 ]
[x10 18
W/cm 2 ]
Mangles
Nature (2004)
RAL 73 6 22 20
2,5
1,6
Geddes
Nature (2004)
L'OASIS 86 2
320 19 11
2,2
Channel
Faure
Nature (2004)
LOA
170 25
500 6 3
0,7
Hidding
PRL (2006)
JETI 47 9
0,32 40 50
4,6
Hsieh
PRL (2006)
IAMS 55
336 40
2,6
Hosokai
PRE (2006)
U. Tokyo
11,5 10 10 80 22
3,0
Preplasma
Miura
APL (2005)
AIST 7 20
432E-6
130 5
5,1
Hafz
PRE (2006)
KERI
4,3 93
200 28 1
33,4
Mori
ArXiv (2006)
JAERI 20 24
0,8 50
0,9
4,5
Mangles
PRL (2006)
Lund LC
150 20 20 5
1,4
Several groups have obtained quasi monoenergetic e beam but at higher density (tL>tp)
LOA
John Adams Insitute, Oxford UK, January 10, 2008

19. GeV electron beams from a « centimetre-scale » accelerator
310-μm-diameter
channel capillary
P = 40 TW
density 4.3×1018 cm−3.
Leemans et al., Nature Physics, september 2006
LOA
John Adams Insitute, Oxford UK, January 10, 2008

20. Summary Part 1 : Laser plasma accelerator : motivation
LOA
Summary
Part 1 : Laser plasma accelerator : motivation
Part 2: Laser Plasma accelerator as injector : Production of monoenergetic electron beam
Part 3 : New scheme of injection : toward a stable, tuneable and quasi monoenergetic electron beam.
Part 4 : Applications
Part 5 :Conclusion and perspectives
John Adams Insitute, Oxford UK, January 10, 2008

21. Controlling the injection
LOA
Controlling the injection
pump
injection
Counter-propagating geometry:
Plasma wave
Principle:
Pump beam
electrons
Injection beam
Ponderomotive force of beatwave: Fp ~ 2a0a1/λ (a0 et a1 can be “weak”)y
Boost electrons locally and injects them: y
INJECTION IS LOCAL IN FIRST BUCKET y
E. Esarey et al, PRL 79, 2682 (1997), G. Fubiani et al. (PRE 2004)
John Adams Insitute, Oxford UK, January 10, 2008

22. Experimental set-up to shadowgraphy diagnostic electron spectrometer
LOA
Experimental set-up
to shadowgraphy diagnostic
electron spectrometer
Probe
beam
LANEX
Gas
jet
B Field
Injection beam
Pump beam
250 mJ, 30 fs ffwhm=30 µm
I ~ 4×1017 W/cm2
a1=0.4
700 mJ, 30 fs, ffwhm=16 µm
I ~ 3×1018 W/cm2
a0=1.2
John Adams Insitute, Oxford UK, January 10, 2008

23. LOA
John Adams Insitute, Oxford UK, January 10, 2008

24. From self-injection to external injection
LOA
From self-injection to external injection
pump
Single beam
ne=1.25×1019 cm-3
ne=1019 cm-3
Self-injection
Threshold
ne=7.5×1018 cm-3
pump
injection
2 beams
ne=7.5×1018 cm-3
John Adams Insitute, Oxford UK, January 10, 2008

25. Optical injection by colliding pulses
LOA
Optical injection by colliding pulses
leads to stable monoenergetic beams
STATISTICS
value and standard deviation
Bunch charge= 19 +/- 6 pC
Peak energy= 117 +/- 7 MeV
DE= 13 +/- 2.5 MeV
DE/E= 11 % +/- 2 %
Divergence= 5.7 +/- 2 mrad
Pointing stability= 2 mrad
*Charge measurements
with absolute calibration
of Lanex film (ICT gave a factor
of 8 higher charge)
John Adams Insitute, Oxford UK, January 10, 2008

26. Monoenergetic bunch comes from colliding pulses: polarization test
LOA
Monoenergetic bunch comes from
colliding pulses: polarization test
Parallel
polarization
Crossed
polarization
John Adams Insitute, Oxford UK, January 10, 2008

27. Controlling the bunch energy by controlling the acceleration length
LOA
By changing delay between pulses:
Change collision point
Change effective acceleration length
Tune bunch energy
Pump beam
Injection beam
2 mm
Gas jet
John Adams Insitute, Oxford UK, January 10, 2008

28. Tunable monoenergetic bunches
LOA
Tunable monoenergetic bunches
pump
injection
late injection
early injection
middle injection
Zinj=225 μm
Zinj=125 μm
Zinj=25 μm
Zinj=-75 μm
Zinj=-175 μm
Zinj=-275 μm
Zinj=-375 μm
J. Faure et al., Nature 2006
John Adams Insitute, Oxford UK, January 10, 2008

29. Tunable monoenergetic electrons bunches:
LOA
Tunable monoenergetic electrons bunches:
190 MeV gain in 700 µm: E=270 GV/m
Compare with Emax=mcwp/e=250 GV/m at ne=7.5×1018 cm-3
John Adams Insitute, Oxford UK, January 10, 2008

30. Summary Part 1 : Laser plasma accelerator : motivation
LOA
Summary
Part 1 : Laser plasma accelerator : motivation
Part 2 : Laser Plasma accelerator as injector : Production of monoenergetic electron beam
Part 3 : New scheme of injection : toward a stable, tuneable and quasi monoenergetic electron beam.
Part 4 : Applications
Part 5 :Conclusion and perspectives
John Adams Insitute, Oxford UK, January 10, 2008

31. GeV acceleration in two-stages
LOA
GeV acceleration in two-stages
Gas-Jet
Laser
Laser
Plasma channel
GeV
1 J
10 TW
30 fs
Nozzle TW
~50 fs
170±20 MeV
30 fs
10 mrad
Density profile rc Δn
Pulse guiding condition : Δn>1/πre rc2 n0
Weak nonlinear effects  more control : a0 ~ 1-2
High quality beams : Lb <λp  n0<1018 cm-3
John Adams Insitute, Oxford UK, January 10, 2008

32. GeV in low plasma density in plasma channel
LOA
GeV in low plasma density in plasma channel
n0= cm-3, 11 J TW
rc=40 μm, Δn=2 n0
Electric field 4
L channel=4 cm
8 cm
12 cm
Electron bunch 3
dN/dE(a.u.) 2
Electric field 1
400
800
1200
Energy (MeV)
Electron bunch
V. Malka et al., Plasma Phys. Control. Fusion 47 (2005) B481–B490
John Adams Insitute, Oxford UK, January 10, 2008

33. Injecting the LOA e-beam @ tbunch = 30 fs, 170 MeV
John Adams Insitute, Oxford UK, January 10, 2008

34. 3 GeV, 1% energy spread e-beam
LOA
3 GeV, 1% energy spread e-beam
E=9 J
P= 0.15 PW
a0=1.5
Parabolic channel:
r0=47 m,
n(r)=n0 ( r/r0)
n0 = 1.1×1017 cm-3
3.5 GeV, with a relative energy spread FWHM of
1% and an unnormalized emittance of mm.
V. Malka et al., PRSTA 9,
John Adams Insitute, Oxford UK, January 10, 2008

35. Material science: g-ray radiography
LOA
Material science: g-ray radiography
High resolution radiography of dense object with a low divergence, point-like electron source
In collaboration with CEA / DAM
Glinec et al., PRL (2005)
John Adams Insitute, Oxford UK, January 10, 2008

36. g-radiography results
20mm
Measured
Calculated
Cut of the object in 3D
Spherical hollow object in tungsten with sinusoidal structures etched on the inner part.
Source size estimation : 450 um
Glinec et al., PRL (2005)
LOA
John Adams Insitute, Oxford UK, January 10, 2008

37. Particle beam in medicine : Radiotherapy
99% Radiotherapy with X ray
LOA
John Adams Insitute, Oxford UK, January 10, 2008

38. Radiation Therapy : context
Photon beams are commonly used for radiation therapy
Photon dose
Photon beam
Dose
tumor
tumor
Depth in tissue
LOA
John Adams Insitute, Oxford UK, January 10, 2008

39. Medical application : Radiotherapy
VHE ELECTRONS
LOA
John Adams Insitute, Oxford UK, January 10, 2008

40. VHE Radiation Therapy Reduced dose in save cells Deep traitement
Good lateral contrast
VHE
Dose
VHE dose
tumor
tumor
Depth in tissue
LOA
John Adams Insitute, Oxford UK, January 10, 2008

41. Clinically approved prostate treatment with seven fields irradiation
LOA
Clinically approved prostate treatment with
seven fields irradiation
Transversal view Sagittal view
John Adams Insitute, Oxford UK, January 10, 2008

42. Improved treatment with electrons
LOA
Improved treatment with electrons
A typical transversal dose distribution with 7 beams.
Electrons
Photons
Difference
A comparison of dose deposition with 6 MeV X ray an improvement of the quality of a clinically approved prostate treatment plan. While the target coverage is the same or even slightly better for 250 MeV electrons compared to photons the dose sparing of sensitive structures is improved (up to 19%).
T. Fuchs, DKFZ in preparation
John Adams Insitute, Oxford UK, January 10, 2008

43. Fudamental aspect : fs radiolysis
H2O (e-s, OH., H2O2, H3O+, H2, H.) e-
Very important for:
Biology
Ionising radiations effects
B. Brozek-Pluska et al., Radiation and Chemistry, 72, (2005)
**Ar.
LOA
John Adams Insitute, Oxford UK, January 10, 2008

44. Compact XFEL: towards a bright X ray source
Reduction of accelerator
Reduction of the undulator
q ~ mrad
10cm
Applications: study of complex structures
(X-ray diffraction, EXAFS) But ps time scale
LOA
John Adams Insitute, Oxford UK, January 10, 2008

45. Parameter designs Laser Plasma Accelerators
LOA
Parameter designs Laser Plasma Accelerators
ELI : > 100 GeV
a0=4
P(PW)
τ (fs)
ne(cm-3)
W0 (μm)
L(m)
E(J)
Q(nC)
E(Gev)
0.12 30
2e18 15
0.009
3.6
1.3
1.12
1.2
100
2e17 47
0.28
120 4
11.2 12
300
2e16
150 9
3.6k 13
112
120
1000
2e15
470
280
120k 40
1120
Golp and UCLA Group
John Adams Insitute, Oxford UK, January 10, 2008

46. Conclusions / perspectives
LOA
Conclusions / perspectives
SUMMARY
Optical injection by colliding pulse: it works !
Monoenergetic beams trapped in first bucket
Enhances dramatically stability
Energy is tunable: MeV
Charge up to 80 pC in monoenergetic bunch
dE/E down to 5 % (spectrometer resolution), dE ~ MeV
Duration shorter than 10 fs.
PERSPECTIVES Q
Combine with waveguide: tunable up to few GeV’s with dE/E ~ 1 %
Design future accelerators
Model the problem for further optimization: higher charge
Stable source:
extremely important
accelerator development (laser based accelerator design)
light source development for XFEL
applications (chemistry, radiotherapy, material science)
John Adams Insitute, Oxford UK, January 10, 2008