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kHz-driven high-harmonic generation from overdense plasmas

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Presentation on theme: "kHz-driven high-harmonic generation from overdense plasmas"— Presentation transcript:

1 kHz-driven high-harmonic generation from overdense plasmas
A. Borot, A. Malvache, X. Chen, R. Lopez-Martens (LOA) J.-P. Geindre, P. Audebert (LULI) G. Mourou (ILE) ICUIL 2010, Watkins Glenn, 29 september 2010 UMR 7639

2 Attosecond pulses from plasma mirrors
Ilaser > nm ne=100’s of nc ne= nc nc = me0wL2/e2 nc = nm ≈ l/10 Optically-polished Solid target Phase-locked harmonics Plasma plume Thaury et al, Nature Physics 3 (2007) Tarasevitch et al, PRL 98 (2007)   Dromey et al, Nature Physics 2 (2006) Nomura et al., Nat. Phys. 5, 124 (2009) Nonlinear medium : Solid density plasma n ~ 1023 cm-3 No intensity limit : (beyond 1020 W/cm2)

3 Different intensity regimes
P Plasma frequency: Plastic target, Thaury et al, , Nature Physics 3 (2007)

4 PIC simulation : 80 nC, sharp gradient, 6.1017W/cm2
Relativistic oscillating mirror (ROM) ~ Doppler effect Bulanov et al, Phys. Plasmas 1 (1994) Lichters et al, Phys. Plasmas 3 (1996) Baeva et al, Phys. Rev. E 74 (2006) plasma Quere et al, PRL 96 (2006) Coherent wake emission (CWE) ~ plasma oscillations plasma

5 Tsakiris et al, New J. Phys. 8 (2006)
Dream beam Laser : ~ 1 Joule, 5fs Tsakiris et al, New J. Phys. 8 (2006) Duration: 5fs Energy: few Joules CEP control I ~ 1020 W/cm2 Temporal contrast: >10-10 Rate > 10Hz 10-4 10-3 10-2 h

6 Albert et al., Optics Letters 2000
Can we do this at 1kHz? Deformable Mirror Target Low f parabaloid Tight focusing 1 mJ, 5 fs 1 kHz Albert et al., Optics Letters 2000 Size of focus ~ 2 “lambda cube” regime Wavefront correction Peak intensity ~ 1019 W/cm2

7 Tough requirements… For the laser: Few-cycle > mJ energy
CEP control High temporal contrast High spatial quality For the target: kHz refreshment sub-mm positioning target lifetime

8 Laser system Femtopower Compact Pro CEP + DazzlerTM
Home made booster amplifier Canova et al., Opt. Lett. 34, (2009) 3mJ, 28fs, 1kHz Dazzler CEP control Forget et al., Opt. Lett. 34, (2009) Hollow fiber compressor 1.5mJ, 4.2fs, CEP<300 mrad Chen et al., Appl. Phys. B 99, (2010)

9 Hollow fiber = excellent spatial quality
1.8 x 1.7 mm2 focus f/1.7 paraboloid (70% energy in focus) …after 6m propagation On-target intensity ~ 3 x 1018 W/cm2

10 ~ 6 million consecutive shots!
kHz target Surface jitter < 1 m translation rotation vacuum chamber translation rotation ~ 6 million consecutive shots! target: 14 cm BK7 ~ 50 mm between shots Target stabilization

11 Reference interferogram
Target stabilization Reference interferogram Mach-Zender interferometer Reference position Target Camera Beam Splitters Frequency stabilised He-Ne laser

12 Target stabilization Fringe tilt Reference Vertical tilt Target Camera
Beam Splitters Frequency stabilised He-Ne laser

13 Fringe spacing increases
Target stabilization Fringe spacing increases Reference horizontal tilt Target Camera Beam Splitters Frequency stabilised He-Ne laser

14 Target stabilization Fringe pattern shifts Reference Depth change
Camera Beam Splitters Frequency stabilised He-Ne laser

15 “on-line” stabilization underway
mm depth (bearing precision) 10 mrad in orientation Current: Manual feedback (picomotors): < 100 nm < mrad few 100 Hz Next: Fast, automated feedback (piezo actuators):

16 Experimental setup laser Vacuum chamber HHG spectrum 50-shot average
Beam expander f/1.7 and f/6 parabola Spherical grating 1200 lines/mm MCP Phosphor CCD HHG spectrum 50-shot average BK7 target

17 HHG divergence vs laser focus
Imax = 8 x 1016 W/cm² Div = 56 mrad 4 x 4.1 mm2 f/6 MCP image Imax = 8 x 1017 W/cm² Div = 186 mrad 1.6 x 1.7 mm2 f/2

18 Full spectrum at 8x1017 W/cm2 (26fs)

19 Relative harmonic efficiencies
I = 8x1017 W/cm² I = 8x1016 W/cm² exponential decay for CWE harmonics

20 Harmonic beam divergence
I = 8x1016 W/cm² I = 8x1017 W/cm² Expected decrease of divergence with increasing harmonic order

21 Laser chirp dependence
I = 8x1016 W/cm² Expected laser chirp dependence Quéré et al, Phys. Rev. Lett. 100, (2008)

22 First “few-cycle” results
HHG spectrum: 28 fs ~ 3x1017 W/cm2

23 First “few-cycle” results
HHG spectrum: 5 fs ~ 3x1017 W/cm2

24 CEP dependence CEP rms stability: > 300 mrad Relative CEP (deg) 100
Harmonic order 100 200 300 Relative CEP (deg)

25 Future work reduce CEP jitter (< 200 mrad)
 attosecond dynamics of CWE upgrade pulse energy up to 5mJ XPW contrast filter: from 108 to >1010  Observe ROM harmonics Lower harmonics : « lambda cube » regime (Naumova et al., Phys. Rev. Lett. 2004)

26 “Salle Noire” Lab at LOA

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