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Title: High-order%20Harmonic%20Generation%20(HHG)%20in%20gases

1
High-order Harmonic Generation (HHG) in gases

by Benoît MAHIEU

2
Introduction

Will of science to achieve lower scales
Space nanometric characterization
Time attosecond phenomena (electronic
vibrations)

? c/?
Period of the first Bohr orbit 150.10-18s
3
Introduction

LASER a powerful tool
Coherence in space and time
Pulsed LASERs high power into a short duration
(pulse)
Two goals for LASERs
Reach UV-X wavelengths (1-100nm)
Generate shorter pulses (10-18s)

Electric field
Continuous
Pulses
time
4
Outline

-gt How does the HHG allow to achieve
shorter space and time scales?
Link time / frequency
Achieve shorter LASER pulse duration
HHG characteristics semi-classical model
Production of attosecond pulses

5
Part 1

Link time / frequency
t / ? (or ? 2p?)

6
LASER pulses

Electric field E(t)
Intensity I(t) E²(t)
Gaussian envelop I(t) I0.exp(-t²/?t²)

I(t)
t time of the mean value
?t width of standard deviation ?t pulse
duration
7
Spectral composition of a LASER pulse
Fourier transform
Pulse sum of different spectral components
8
Effects of the spectral composition

Fourier decomposition of a signal
Electric field of a LASER pulse
More spectral components gt Shorter pulse
Spectral components not in phase ( chirp ) gt
Longer pulse

9
Phase of the spectral components

Time

Frequency

Fourier transform
Phase of the ? component
chirp no chirp
chirp -
No chirp minimum pulse duration
Phase of each ?
All the ? in phase
Moment of arrival of each ?
Electric field in function of time
10
Fourier limit

Link between the pulse duration and its spectral
width
Fourier limit ?? ?t ½
For a perfect Gaussian ?? ?t ½

Fourier transform
?t pulse duration
?? spectral width
I(?)
I(t)
1
t
?
I(t)
I(?)
2
t
?
I(t)
I(?)
3
t
?
11
Part 1 conclusionLink time / frequency

A LASER pulse is made of many wavelengths inside
a spectral width ??
Its duration ?t is not free ?? ?t ½
?? ?t ½ Gaussian envelop pulse limited
by Fourier transform
If the spectral components ? are not in phase,
the pulse is lengthened there is a chirp
Shorter pulse -gt wider bandwidth no chirp

12
Part 2

Achieve shorter LASER pulse duration

13
Need to shorten wavelength

Problem pulse length limited by optical period
Solution reach shorter wavelengths
Problem few LASERs below 200nm
Solution generate harmonic wavelengths of a
LASER beam?

at ?800nm Pulse cant be shorter than period!
T2,7 fs
at ?80nm (? c T)
T270 as
14
Classical harmonic generation

In some materials, with a high LASER intensity
Problems
low-order harmonic generation (?/2 or ?/3)
crystal not below 200nm
other solutions not so efficient

BBO crystal
2 photons Eh?
1 photon Eh2?
?0 800nmfundamental wavelength
?0/2 400nmharmonic wavelength

15
Dispersion / Harmonic generation

Difference between
Dispersion separation of the spectral components
of a wave
Harmonic generation creation of a multiple of
the fundamental frequency

I(?)
?
I(?)
I(?)
2nd HG (Harmonic Generation)
?
?
?0
2?0
16
Part 2 conclusion Achieve shorter LASER pulse
duration

Pulse duration is limited by optical periodgt
Reach lower optical periods ie UV-X LASERs
Technological barrier below 200nm
Low-order harmonic generation not sufficient
One of the best solutionsHigh-order Harmonic
Generation(HHG) in particular in gases

gas jet/cell
?0
?0/n
17
Part 3

HHG characteristics
Semi-classical model

18
Harmonic generation in gases
Grating
Gas jet
LASER source fundamental wavelength ?0
Number of photons

Classical HG
Low efficiency
Multiphotonic ionization of the gas n h?0 -gt
h(n?0)
gt Low orders

Harmonic order n
LASER output harmonic wavelengths ?0/n
(New Ward, 1967)
19
Increasing of LASER intensity

Energy e 1J
Short pulse ?t lt 100fs I e/?t/S gt 1018
W/cm²
Focused on a small area S 100µm²

Intensity
Pulse length
1019
W/cm²
? 800nm
100ns
1015
100ps
1013
100fs
1fs
109
Years
1967
1988
HHG
20
High-order Harmonic Generation (HHG) in gases
Grating
Gas jet
plateau
LASER source fundamental wavelength ?0
cutoff
Number of photons

How to explain?
up to harmonic order 300!!
quite high output intensity
Interest
UV-X ultrashort-pulsed LASER source

Harmonic order n
LASER output harmonic wavelengths ?0/n
(Saclay Chicago, 1988)
21
Semi-classical model in 3 steps
hnIpEk
-
-
Ip
-
-
-
-
-
w0t 0
1
Electron of a gas atom Fundamental state
P.B. Corkum PRL 71, 1994 (1993)
K. Kulander et al. SILAP (1993)
Periodicity T0/2 ? harmonics are separated by 2w0
Energy of the emitted photon Ionization
potential of the gas (Ip) Kinetic energy won by
the electron (Ek)
22
The cutoff law

Kinetic energy gained by the electron
F(t) qE0 cos(?0t) F(t) m a(t)
a(t) (qE0/m) cos(?0t)
v(t) (qE0/?0m) sin(?0t)-sin(?0ti)ti
ionization time gt v(ti)0
Ek(t) (½)mv²(t) ? I ?0²
Maximum harmonic order
h?max Ip Ekmax
h? ? Ip I ?0²
Harmonic order grows with
Ionization potential of the gas
Intensity of the input LASER beam
Square of the wavelengthof the input LASER
beam!!

h?max Ip Ekmax
plateau
cutoff
Number of photons
Harmonic order n
The cutoff law is proved by the semi-classical
model
23
Electron trajectory
Electron position
x(ti)0 v(ti)0
x

Different harmonic orders
different trajectories
different emission times te

Time (TL)
0
1
If short traj. selected (spatial filter on
axis)
Harmonic order
Short traj.
Long traj.
Positive chirp of output LASER beam on attosecond
timescale the atto-chirp
21
Chirp gt 0
Chirp lt 0
19
17
15
Mairesse et al. Science 302, 1540 (2003)
0
Emission time (te)
Kazamias and Balcou, PRA 69, 063416 (2004)
24
Part 3 conclusionHHG characteristics
gas jet/cell

Input LASER beamI1014-1015W/cm² ??0
linear polarization
Jet of rare gasionization potential Ip
Output LASER beamtrain of odd harmonics ?0/n,
up to order n300 h?max ? Ip I.?0²
Semi-classical model
Understand the process
Tunnel ionization of one atom of the gas
Acceleration of the emitted electron in the
electric field of the LASER -gt gain of Ek ? I?0²
Recombination of the electron with the atom -gt
photoemission EIp Ek
Explain the properties of the output beam -gt
prediction of an atto-chirp

?0
?0/n
Number of photons Eh?
h?max IpEkmax
Plateau
Cutoff
Order of the harmonic
25
Part 4

Production of attosecond pulses

26
Temporal structure of one harmonic

Input LASER beam
?t femtosecond
?0 800nm
One harmonic of the output LASER beam
?t femtosecond
?0/n some nanometers (UV or X wavelength)
-gt Selection of one harmonic
Characterization of processes at UV-X scale and
fs duration

Intensity
Intensity
Harmonic order
Time
27
Sum of harmonics without chirp an ideal case

Central wavelength ??0/n -gt ?0 800nm
order n150 ?5nm
Bandwidth ?? -gt 25 harmonics i.e. ??2nm
Fourier limit for a Gaussian ?? ?t ½
??/? ??/? ? c/?
?? c ?? (n/?0)²
?t (?0/n)² (1/c?? )
?t 10 10-18s -gt 10 attosecond pulses!
If all harmonics in phasegeneration of pulses
with ?t T0/2N

E(t)
Time
10 fs
Intensity
T0/2
T0/2N
Time
28
Chirp of the train of harmonics

Problem confirmation of the chirp predicted by
the theory
During the duration of the process (10fs)
Generation of a distorted signal
No attosecond structure of the sum of harmonics

Emission times measured in Neon at ?0800nm I4
1014 W/cm2
T0/2
T0/2N
Intensity
10 fs
Time
29
Solution select only few harmonics
(Measurement in Neon)
H25-33 (5)

Mairesse et al, 302, 1540 Science (2003)
Mairesse et al, Science 302, 1540 (2003)
Y. Mairesse et al. Science 302, 1540 (2003)
Optimum spectral bandwith
30
Part 4 conclusionProduction of attosecond pulses