Transcript Slide 1

Basic principles of ultrafast lasers
Components of ultrafast laser system
Pump
Mode-locking
Dispersion
OC
HR
Gain
Mechanism
Compensation
Cavity modes
ln = 2 L/n
D f = c/2 L
Concepts of Mode Locking
Mode locking is a method to obtain ultrafast pulses from lasers, which are then
called mode-locked lasers mode
RANDOM
LOCKED phases
phase for
forall
allthe
thelaser
lasermodes
modes
Irradiance vs. Time
Out of phase
Out of phase
In phase
Time
Out of phase
Time
Basic principles of ultrafast lasers
Bandwidth vs Pulsewidth
broadest
broader spectrum
spectrum
DnDt = const.
bandwidth
narrow
spectrum
Dn
duration
continuous
wave
Dt (CW)
pulses
shortest
(mode-locked)
pulses
Mode-locking Mechanisms
Active mode-locking
Acousto-optic modulator
 Synchronous pump mode-locking

Passive mode-locking
Saturable absorber (dye, solid state)
 Optical Kerr effect

cw
Power
Power
Types of Laser Output
Time
Time
Power
Power
Time
Q-switch
cw ML
Q-sw.ML
Time
Kerr-Lensing
Kerr medium (n = n0 + n2I)
Low-intensity beam
High-intensity ultrashort pulse
Focused pulse
Optical Kerr Effect
Intensity dependent refractive index: n = n0 + n2I(x,t)
Spatial (self-focusing)
• provides loss modulation with suitable
placement of gain medium (and a hard aperture)
Temporal (self-phase modulation)
• provides pulse shortening mechanism with
group velocity dispersion
Optical Kerr Effect
Refractive index depends on light intensity: n (I)= n + n2 I
self phase modulation due
to temporal intensity variation
self-focusing due to
transversal mode profile
Group Velocity Dispersion (GVD)
Optical pulse in a transparent medium stretches because of GVD
• v = c / n – speed of light in
a medium
• n –depends on wavelength,
dn/dl < 0 – normal dispersion
• High-intensity modes have smaller cross-section and are less lossy. Thus, Kerr-lens is
similar to saturating absorber!
• Some lasing materials (e.g. Ti:Sapphire) can act as Kerr-media
• Kerr’s effect is much faster than saturating absorber allowing one generatevery
short pulses (~5 fs).
GVD Compensation
GVD can be compensated if optical pathlength is different for “blue” and “red”
components of the pulse.
Prism compensator
Wavelength
tuning mask
“Red” component of the pulse propagates in glass where group velocity is
smaller than for the “blue” component
Components of an Ultrafast Laser
Pulse shortening mechanism
•Self phase modulation and group velocity
dispersion
Dispersion Compensation
Starting Mechanism
Regenerative initiation
•Cavity perturbation
•Saturable Absorber (SESAM)
Cavity configuration of Ti:Sapphire laser
Tuning range 700-1000 nm
Pulse duration < 20 fs
Pulse energy < 10 nJ
Repetition rate 80 – 1000 MHz
Pump power: 2-15 W
Typical applications:
• time-resolved emission
studies
• multi-photon absorption
spectroscopy
• imaging
Amplification of fs Pulses
Concept:
• Stretch femtosecond oscillator pulse by 103 to 104 times
• Amplify
• Recompress amplified pulse
Oscillator
Stretcher
Amplifier
Compressor
Chirped pulse amplification
• Femtosecond pulses can be amplified to petawatt powers
• Pulses so intense that electrons stripped rapidly from atoms