Post on 04-Mar-2015
Ultrafast X-ray and Ion
sources
from multi-PW lasers
Matt Zepf
Queen’s University Belfast
Outline
• Ion Acceleration via Radiation Pressure Acceleration
– GeV/u
– Narrow energy distributions
– Attosecond ion bunches
– First demonstration of ‘Light-sail’ regime
• Relativistically Oscillating Mirrors (HHG from Solid Targets)
– Relativistically oscillating mirrors
– Attosecond and zeptosecond pulses
– Extreme brightness with ELI conditions
• Relativistic Mirrors
– Light Sail Regime (thin target)
– Holeboring regime (Semi-infinite target)
I>1019Wcm2
a0>3
Relatvistic electron production
Hot electron propagation
MeV energy, µC charge
Space charge field:
E~Thot/ Debye~MeV/µm=1012V/m
MeV/u protons and ions
Typical targets: Metallic foils
Proton Source: CH Contamination on foil surfaces (typically ~50Å)
THE TNSA Mechanism
(Target Normal Sheath Accleleration))
Target
Typical results
106
107
108
109
1010
1011
Pro
tons/
MeV
40353025201510
Proton Kinetic Energy (MeV)
15 J 42 J 110 J
• Target: 10µm Al
• Temperature
~ 1.8 MeV for 12 J
~ 5 MeV for 85J
• Energy conversion
~2 10-3 for 12 J
~5 10-2 for 85 J
~1 10-1 for 400 J
• Efficiency at 30-35 MeV
hot~10-5-10-4
10 MeV 22 MeV17 MeV
Typical divergence:
30-60°
Beam quality
nm scale surface perturbations are still visible
- irreducible emittance of <0.004 mm mrad
From Cowan et al, PRL 2004
µm scale
virtual source
30-60° divergence
x ~10-3mm x 1 rad ~ 1 mm mrad
Excellent probe for
fields in plasmas
(M. Borghesi et al.)
Plasma
Laser accelerated protons
- an exciting source for the future
• Unique for short pulse duration
– Unrivalled for time resolved probing
– Excellent emittance
• Compared to conventional acceleratorswhat do we need to be competitive?
– Higher average flux
– Narrow angular distribution
– Narrow energy distribution (not simply slicing)
– Higher endpoint energy• 200 MeV protons required for 200mm range in H2O (e.g.
for hadron therapy)
• Fewer particles at higher repetition rate (e.g. hadron therapy)
Beam energy scaling – typically ~I1/2
(Robson, et al., Nature Physics (2006)
500fs scaling: 200 MeV protons requires >4 1021Wcm-2 (>1kJ)
Schreiber Scaling: 200 MeV at 100J, 40fs
Efficiency into >200 MeV around 10-5-10-4 !
Can we do better?
Schreiber et al., PRL (2006)
A novel approach is required -
Radiation Pressure Acceleration (RPA)
Extreme Laser pressure at high intensities:
PL=2I/c=6 Gbar @ 1019Wcm-2
Velocity estimated by momentum conserv.
(accelerated mass balances laser momentum)
niMivi2= vi
2=I/c
vi=(I/ c)1/2
Ei~IRadiation Pressure Accelearation scales faster
than TNSAWilks et al (PRL 92)
Zepf et al., Phys. Plasmas (1996)
30fs
60fs
Relativisitic equations of motion for whole foil acceleration: LIGHT SAIL REGIMEL
~I/ niMiL
Radiation Pressure Acceleration- using circular polarisation (e.g. Robinson, Zepf et al, New J. Phys, 2008)
Ch
arge d
ensity
x
~ I/
At I>1023 Wcm-2RPA dominates over TNSA:
GeV protons with quasi-monoenergetic
distribution for Elaser=10kJ(Simulations by Esirkepov et al., PRL 175003 (2004))
Far beyond ELI first stage…
In the limit of thin foils, extreme intensity: Ep~ GeV
Intermediate intensity - RPA and TNSA coexist
TNSA~I1/2
At 5 1020 Wcm-2 acceleration
due to radiation pressure
becomes comparable to TNSA.
Can we exploit the faster
Emax I scaling?
L.O. Silva et al. PRL 92, 015002 (2004)
RPA
Problem: TNSA decompresses foil during RPA
=> Foil becomes transparent!
Radiation Pressure Acceleration-circular polarisation suppresses TNSA
For I=1021 Wcm2
Circular polarisation suppresses hot electron generation - no TNSA, few -rays
RPA dominates for realistic intensities.
102
100
101
x[µm]
0 5 10
40
20
0
y[µ
m]
200 600 1000 200 600 1000Energy [MeV] Energy [MeV]
Pro
ton
Nu
mb
er (
a.u
.) 105
104
103
102 Pro
ton
Nu
mb
er (
a.u
.) 105
104
103
102
x[µm]80 120 160
x[µm]80 120 160
1.5
1
0.5
-0.5
0
1.5
1
0.5
-0.5
0
106
105
102
101
104
103
px/m
pc
Px/m
pc
RPA – Circ Pol TNSA- Linear
(Robinson et al, NJP 2008)
Foil thickness:100nm150nm
250nm350nm
RPA scaling - a promising route
Time (fs)
0 100 200 300 400 400
500
400
Pro
ton
en
ergy [
MeV
]
300
200
100
0
Co
nversio
n E
fficie
ncy
1
.8
.6
.4
.2
200 MeV predicted in quasi-monoenergetic beam at ~ 1021 Wcm-2
Feasible ELI specfication laser at high repetition rate
Efficiency into 200 MeV peak >60%
Divergence angle: 4°
Quasi-monoenergetic proton beams from RPA
- first experimental demonstration
Data from LIBRA
consortium taken on
Astra GEMINI
Transition to the light-sail regime
I=4 1020Wcm-2
I=9 1020Wcm-2
Ep~I1.75
Ep~I0.8
Light Sail: acceleration to GeV/uat ELI parameters
Stable acceleration to GeV energies shown for I=2…6 10 22 Wcm-2
(Simulations: B. Qiao et al, PRL 2009)
Control of laser or target radial distribution essential for ultimate performance
Solid density bunch
Duration:100nm/c= 0.3 fs
bea
m
dir
ecti
o
n
Fs
cat
Fg
rad
Hi-Rep strategy for complex targets
Wafer target production
Electrostatic Injection
Optical trapping
RPA light sail – the story so far.• RPAwith circular polarisation.
• Low divergence
• High efficiency
• Quasi-Monoenergetic distribution
• Little other radiation (gammas, fast electrons)
• Unique features• Extremly short bunches – attosecond duration
• Solid density bunches (quasi-neutral)
• Synchronisation to optical sources at attosecond level possibl
• Challenges• Maintaining 1D nature during acceleration.
• High repetition, high power lasers to drive accelerator
• GeV accelerator simulation E=0.5- 2kJ, 30 fs
• 200 MeV: E~100J, 60 fs,
Ultrafast probing
Ultrabright laser driven attosecond sources
1) Relativistically Oscillating
Mirrors
Extreme Intensities
Coherent Harmonic Focusing
Attosecond Bunching
Tests of QED using the Relativistically Oscillating Mirror
Relativistically Oscillating Plasma Surfaces
as non-linear medium
Electron kinetic energy = rest mass for a0=(I 2/1.37 1018Wcm-2)1/2=1
Highly relativistic for a0>>1 ( ~a0)
Relativistically Oscillating Surface
Courtesy of G. Tsakiris, MPQ
fout
f in
1 v /c
1 v /c~ 4 2 tout
tin~
1
4 2
Shorter Pulses - Higher Frequencies
The relativistic Doppler effect
=33
ELI laser can generate Relativistic Mirrors
=10fs, =800nm
=2.5as, =2Å,
Plasma
Laser Driven Oscillation
X(t)
Rest
Position
vs
c
t´
Upshifting from an oscillating surface
γs
t´
At these times high harmonics are generated!
s
1
1 vs c2
~T0/ max
1)Upshifting is restricted to a short time ~T0/ max.
2)The upshifted pulse has a duration of O~ / ~ T0/
From Fourier theory, the spectrum must extend to frequencies O~
Predicted pulse duration ~10-19s=100zeptoseconds for =20
A sufficiently intense laser can be used to move electrons in a
target at relativistic velocities.
A sharp edged plasma will act as an oscillating, relativistic mirror.
with = [1+a02/2]1/2
10-30 is possible with latest lasers
Gordienko et al. PRL 93, 115001, 2004
Orders > 1000,
keV harmonics!
asymptotic efficiency ~n-8/3for >>1
Harmonics up to nmax~81/2
Independent of intensity!
Dromey et al., Nature Physics, (2006.)
Experimental data
From Vulcan PW
• Boost due to
– Increased focusability
– Attosecond pulse duration
Enhancement up to the Schwinger limit theoretically possible(Gordienko et al. PRL,94, 103903 (2004)
HHG BOOSTS theoretically achievable intensity.
• How realistic is this in the real world?
– No phase distortions on target.
– No scattering of higher harmonic due to surface
roughness.
Ideal world: focal spot size reduced by n2
FLAT SURFACE
Diffraction limited n= Laser/n
At a0>>1
Laser
Target
PARABOLIC SURFACE
Divergence: =f/D
Diffraction limited focus ~f n/D
Reflected Laser
Focusing
Harmonic
Target Laser
Dynamic effects: Ponderomotive Denting
0 10 20 30x (c/ 0)
0
10
20
30
y (
c/
0)
100 fs
PLASMAVacuum
Laser
Ponderomotive denting due to Gbar
light pressure
f
DHARMONIC
BEAM
Harmonics emitted into constant angle even for initially flat targets
n=Max( Laser/n, f/D)
(from Wilks et al. PRL 1992)
Experimental Results
Wavelength (nm)
An
gle
(m
rad
)
ROM orders
CWE orders
Diffraction limit
I=2 1019Wcm-2
p=50fs
From: Dromey, Zepf, Nature Physics, 5, 146, 2009
500fs, 1020 Wcm-2
50fs, 1019 Wcm-2
Divergence vs harmonic order
Experimental dent vs PIC
GAUSSIAN FOCUS
SUPERGAUSSIAN
WAVEFRONT CONTROL
Preshaped targets (laser machining in situ?)
Pulse duration (5fs -> 2mrad divergence in above expt.)
Intensity distribution (supergaussian)
Divergence and focus control
From Hörlein et al,
EPJ D 55, 475–481 (2009)
Simulations by S. Rykovanov
• Changing roughness does not affect specular reflection –
data consisten with denting only
• Specular reflection observed for initial roughness > n
Is target roughness a limiting factor ?
- diffuse or specular reflection for high orders
Dromey et al, PRL 99, 085001 (2007)
keV harmonics are beamed
• Initial roughness of target is smoothed out
– Simulations by Sergey Rykovanov.
• Focusing to extreme intensities appears feasible
Relativistic plasma dynamics smooth initial roughness
0.01
0.1
1
10
100
1000
10 100 1000 10000
Puls
e d
ura
tio
n (
as
)
nF
Duration of attosecond pulses
n=(21/p-1)nF
Few as pulses
possible <1keV
Zeptosecond@
>1keV
nF
Extremely short pulses are possible
Harmonic efficiency slope as n-p
Harmonics 10 -14 (CWE)
XUV pulse train with ~0.9 fs duration
(in collaboration with MPQ at ATLAS)
Y. Nomura et al., Nature Physics 2009
Attosecond pulse measurement
• Pulse duration reduces
with n:
~n-1
• Diffraction limited
focus:
w0~n-2
Peak intensity of attosecond pulses
• Single harmonic
efficiency:
~n-8/3
• Pulse efficiency (for ~n
harmonics forming the
as pulse)
~n-5/3
34
21
35
max nnn
n
A
EIIntensity increases:
Opens up new regime of high intensity X-ray science
Tool for probing vacuum physics
Coherent superposition of entire spectrum ICHF=a03 I0
Probing vacuum bi-refringence
X-ray
probe
2d
probe
n4
15
d
probe
I
IcritPhase Shift:
Probe wavelength as short as possible (polarised X-ray)
Intensity as high as possible, long interaction length
2
2
2
ellipticity:
• Requires bright polarised X-ray probe
• Requires time synchronisation << laser
• Requires ultra-intense laser >>1024 Wcm-2
• Requires excellent polariser
Practical experiments are challenging
X-ray
probe
Ultraintense laser
(e.g. ELI
Polariser
Reflected Laser
Focusing
Harmonic
Target Laser
Relativistic Mirrors for experimental QED?
-Boosted intensity by CHF
-Harmonics are intrinsic probe of CHF
I[Wcm-2] Length 2
1µm 1022 20 3.8 10-10 1.5 10-19
1nm 1022 20 3.8 10-7 1.5 10-13
1Å 1024 20 0.002 1 10-6
1Å 1026 2 0.02 1 10-4
What magnitude do we expect?
X
X
• Intensity boost via CHF and synchronised short
wavelength probe makes observation feasible
(measurement limit of 2 to date ~ 10-6)
• How well polarised are the harmonics (the high
power laser?)
Summary
• Extreme Intensities beyond current limit
– Coherent Harmonic Focusing
– Attosecond bunching
• Ultrabright attosecond source
• Well suited to tests of QED
• Extreme X-ray physics
Ultrabright laser driven attosecond sources
2) Relativistic Flying Mirrors
Extreme Intensities
Coherent Harmonic Focusing
Attosecond Bunching
Tests of QED using the Relativistically Oscillating Mirror
Relativistic Flying Mirror
Reflectivity:For =const expect upshift of r/ i=4 z
2; NOTE: 4 z2~2 <<4
Coherent reflection: L< (ki z2)-1
Bulanov S V et al PRL 2003; B. Qiao et al, NJP 2009
z
Blowout condition:
a0=60, n/nc=200, z~7; max~100
PIC confirms upshift + Reflectivity (B. Qiao et al.,NJP 2009)
z2~213
Chirp produces broad spectrum
A bright, monochromatic future?
Laser vg=c~vfoil => interaction time >> laser
= (t) => Strong chirp in upshift
Possible solution: secondary foil to reflect drive laser and transmit
Relativistic Mirror
=const => monochromatic upshift
Wu+Meyer-ter-Vehn:
2nd foil enables z= max
(arXiv:1003.1739)
Ultrabright narrowband sources
at 100s of keV are possible
Towards bright coherent -rays
SUMMARY.
• ELI Beamlines facility is ideall placed to exploit emerging laser driven sources
• Radiation Pressure Ion sources
• Ultrashort bunches
• Compact accelarators to GeV/u level
• Science and Medical applications
• Relatvistic mirror sources
• Ultrabright attosecond sources
• Extreme X-ray Intensities possible (extreme source brightness with ELI)
• Towards zeptosecond regime
• Narrowband X-ray and Possibly -ray with Relativistic Flying Mirror
Ultrafast probing
Light-Sail and Holeboring regime
Holeboring Regime
a~I/
Ch
arge d
ensity
x
Light Sail Regime
a~I/
Holeboring acceleration takes place in thick target limit
=> more relaxed requirements
Acceleration depends on local intensity for sufficiently short pulses!
Ultra-short pulses (here 4 cycles) reduce energy requirements.
Gaussian foci acceptable (reduced energy requirements)
From Macchi et al. PRL 2005
Acceleration Propagation phase
Dimensionless holeboring parameter:
Target:
~0.2
Holeboring – I/ scaling
0
0.05
0.1
0.15
0.2
0.25
0.3
0.35
0.4
1020 1021 1022 1023 1024
70.8 kgm^(-3)30 kgm^(-3)1000 kgm^(-3)
Intensity (Wcm-2)
Low density targets are desirable
Liquid H2, 30 fs pulse
Liquid H2, 30 fs pulse.
Spectral control possible by tailoring pulse shape/density profile: I/ =const.
1021Wcm-2 6×1021Wcm-2
6×1022Wcm-21022Wcm-2
Existing Hydrogen Jets are suitable for Holeboring
Holeboring acceleration.• Desirable features.
• High efficiency
• Quasi-Monoenergetic distribution possible
• Little other radiation (gammas, fast electrons)
• Semi-infinite targets
• Gaussian foci (no 1D requirement)
• Suitable for current high repetition rate technology• For I=6 1022 Wcm-2: E= 5J, 1µm focus, 10fs
=> These are PFS parameters to a achieve 400 MeV/u
• Challenges• Maintaining 1D nature during acceleration.
• High repetition, high power lasers to drive accelerator
• GeV accelerator simulation E=0.5- 2kJ, 30 fs
• 200 MeV: E~100J, 60 fs,
Summary - Protons
• Laser accelerated protons (TNSA)– Excellent beam emittance
– Unique beam characteristics – excellent short pulse ion source
– ps temporal resolution of electric field evolution
– But:Slow scaling to high beam energies, broad spectrum
• RPA schemes
– Highly desirable beam qualities with circular polarisation.• Low divergence
• High efficiency
• Quasi-Monoenergetic distribution
• Little other radiation (gammas, fast electrons)
– Potentially ideal for medical applications.
– Excellent laser beam control is essential for light sail
– Relaxed operating conditions for holeboring regime
• High repetition, high energy beams appear within reach.
Plasma Mirror
- an ultra-fast optical switch
A low reflectivity surface (i.e. a piece of glass with AR coating can operate as
~100fs rise time optical switch:
- Illuminate with Imax> plasma formation threshold
- prepulse sees Rcold<10-2
-main pulse sees Rplasma~60-80%
- contrast enhancement: Rplasma/Rcold~ 100
Disadvantages: Energy loss, new PM required every shot.
A
A
A
Plasma
Mirror
Advantage: Interaction with near-perfect plasmas surfaces is possible.
Experimental set-up
15Mev
0
5
10
15
20
25
30
35
40
0 500 1000 1500 2000 2500
5Mev 10Mev
Detector depth [µm]
Proton energy loss
En
erg
y lo
ss [K
eV
/µm
]
0
5
10
15
20
25
30
35
0 5 10 15 20 25
layer Alayer B
RCF layer number
Pro
ton
en
erg
y [M
eV
]
Layered detector stacks give 2D energy resolved beam images
Detector Stack
Quasi-monoenergetic proton beams from RPA
- first experimental demonstration
0
2 1012
4 1012
6 1012
8 1012
1 1013
4 8 12 16 20
Pro
ton
s/M
eV
/sr
Energy [MeV]
-1 1013
0
1 1013
2 1013
3 1013
4 1013
5 1013
6 1013
7 1013
0 5 10 15 20 25
Pro
ton
s/M
eV
/sr
Energy [MeV]
Astra Gemini results
LIBRA consortium
Beam quality - spectral
1ps
E
t 100ps
E
t200ps
Typical conventional accelerator @20MeV E/E=10-4 :
E t~2keV*10ns=20 10-6 eV s
Laser accelerator: E t~10 MeV*1ps=10 10-6 eV s
Comparable to conventional accelerator
After phasespace rotator
Circular polarisation
- suppression of foil heating and expansion
Copious hot electrons
TNSA
Gamma ray production
No hot electrons
Suppressed TNSA (foil expansion)
Fewer gamma rays
Simulations by Sergey Rykovanov, MPQ (published
Reflected waveform contains attosecond bursts of harmonics every at
every -spike
t
a)
Laserf
IFT
c)
f
I
d)
FT
t
I
e)
t
E
b)
E
t
Many cycle interaction
Attosecond pulse generation
For a few cycle pulse the highest harmonics are only generate in one cycle
-> isolated attosecond pulse
t
IFT
e)
t
a)
f
I
d)
f
IFT
c)
E
t
t
E
b)
Few cycle interaction
Attosecond pulses by spectral filtering
Removing optical harmonics + fundamental changes wave
from from saw-tooth to individual as-pulses
from (G. D. Tsakiris et al.,New J. Phys. 8, 19(2006)
0
0.2
0.4
0.6
0.8
1
-15 -10 -5 0 5 10 15
CircularLinear
|E|
Time [fs]
Electric field does not oscillate for circular polarisation –
light pressure becomes quasi-static
P~I/c~E2/c