1. Precision Control Optical Pulse Train
Long-Sheng Ma2,1, Zhiyi Bi2, Albrecht Bartels3, Kyoungsik Kim3
Lennart Robertsson1, Massimo Zucco1, Robert S. Windeler4
Guido Wilpers3, Chris Oates3, Leo Hollberg3, Scott A. Diddams3
1Bureau International des Poids et Mesures, Pavillon de Breteuil, Sevres, FRANCE.
2Key Laboratory of Optical and Magnetic Resonance Spectroscopy,
East China Normal University, Shanghai , CHINA
3National Institute of Standards and Technology, 325 Broadway, Boulder, CO , USA.
4OFS Laboratories, 700 Mountain Avenue, Murray Hill, New Jersey 07974, USA

2. Femtosecond laser frequency comb
Pump
532 nm
Ti:Sapphire t
E(t) f
Time t
frep
frep
Frequency f f0
f(N) = fo + N frep

3. RF-Referenced Femtosecond Laser Frequency CombH
maser
f(N) = fo + N frep
Phase
Locks
Δf(N) =Δf ceo + N ×Δf rep
frep fo fo fr
Femtosecond
Laser Frequency
Comb f
1/frep
Time PD
Spectrum of PD output
Microwave Freq.
frep

4. Link the Beating between Two CombsfR
Femtosecond Laser
Synthesizer 1
f1(k1)
frep1
fceo1
fb1
fceo1
frep1
Phase Control
frep1 = frep2
fceo1 = fceo2 H
maser
fb1+ fb2
Phase Control
fceo2
frep2
fb2
frep2
fceo2
Femtosecond Laser
Synthesizer 2
f2(k2)

5. The Agreement among Three Femtosecond Laser Combs
Ma, et al. Opt. Lett.29, 641 (2004)
Df [ECNU-C1 – BIPM-C1] = 0.15 Hz uc = 1.24 Hz
Df [BIPM-C2 – BIPM-C1] = 0.09 Hz uc = 0.83 Hz
Df [ECNU-C1 – BIPM-C2] = 0.06 Hz uc = 1.49 Hz
The measured frequency is 563 THz.
Including all the 21 data points the average difference is 0.11 Hz with uc = 0.69 Hz.

6. Optically-Referenced Femtosecond Laser Frequency Comb
fb = fL - f(N)
= fL – (fo + N frep )
Phase
Locks fb fo fo fr
fL (reference laser)
Femtosecond
Laser Frequency
Comb f no
frep
frep = ( fL - fceo - fb )/N

7. Femtosecond Laser Frequency Combs
Albrecht Bartels (lasers), Bob Windeler (fiber)
Conventional 1 GHz Laser
Ti:Sapphire
Gain
532 nm
Pump
input
~20 mm
Broadband 1 GHz Laser
Ti:Sapphire
Gain
convex
532 nm
Pump
Two things must be controlled: rep rate, optical frequency
Both Systems have:
PZT for fRep. control
AOM for f0 control

8. Configuration of Transportable Comb
RF Synthesizer
H-maser
RF Synthesizer
RF band pass
filter fceo
PLL
fceo P
RF band pass
filter frep
PLL
frep HV
Amp RF
Amp
AOM D Ti
SHG
532 nm M3 Mp
λ/2
Periscope
λ/2
λ/2
1064 nm
600 to
900 nm M2 M1
PCF

9. Configuration of Broadband CombRF
Synthesizer H
maser RF
Synthesizer
Cavity stabilized laser f657
PLL fb D
frep D
Delay stage
fceo
THG
PLL
fceo
PMT
BBO
Single mode
UV optical fiber
960 nm HV
Amp
480 nm
320 nm
λ/2
960 nm
KNbO3
SHG
SHG
Delay stage
PZT
640 nm
BBO
AOM
λ/2
Pump laser
( 532 nm ) RF
Amp

10. Link the Beating between Two Combs by synchronization of optical pulse
Femtosecond
Laser Frequency
Comb 1
Optical Frequency
Reference fL
Filter
Femtosecond
Laser Frequency
Comb 2
counter
Photodiode

11. frep1 = ( fL - fceo1 - fb1 )/N1 (1)
When N1 = N2 = N
Δf rep is independent of fL
Δf = f1(N) - f2(N)
= Δf ceo + N × Δf rep
frep2 = ( fL - fceo2 - fb2 )/N (2)
f1(N1) = fceo1 + N1 × frep (3)
f2(N2) = fceo2 + N2 × frep (4)
Any small difference of repetition rate between two combs is enhanced by N in optical beating. ( N ~ 5 × 105 )
When frep1 = frep2 and the relative phase between the optical trains from the two combs is set to zero, all the modes that are appropriately phased generate a strong beat signal with signal-to-noise as high as 60 db within a 300 kHz bandwidth.

12. Optical-to-optical Comparison of Four combs
Ma, et al. Science 303, 1843 (2004)
2003
Confidence level is 95%

13. Testing the Optical pulse train
Femtosecond
Laser frequency
Comb 1
nonlinear
cross-correlation
Optical
Frequency
Reference fL
PMT
counter
Femtosecond
Laser Frequency
Comb 2

14. Comparisons of Repetition Rate using Nonlinear Cross-correlation

15. Summary
The uncertainty (potential limitation) of an optically-referenced femtosecond laser synthesizer has been measured
Optical-to-optical: <110-19
Optical-to-microwave (pulse train): 2  10-18
2. The uncertainty (“accuracy”) of an H maser-referenced femtosecond laser comb has been measured
Microwave-to-optical: < 1 Hz (~10-15 level )
For optical frequency metrology
Limitation is due to the noise of RF synthesizer

16. 飞秒激光光梳 f(N) = fo + N frep f Time Frequency t E(t) t
Pump
532 nm
Ti:Sapphire t
E(t) f
Time t
f(N) = fo + N frep
frep
frep
Frequency f f0
f(N)×2 - f(2N) = 2 fo + 2N frep- fo - 2N frep = fo

17. Why test the femtosecond laser frequency comb?
It will be the “gears” of future optical clocks with projected fractional uncertainties approaching 110-18
It is used for calibration of world length standards to provide traceability to the SI second.
Different type of the combs now exist and their merits should be compared
Microstructure fiber systems vs. broadband lasers
At what level will noise from the microstructure fiber affect the performance of the synthesizer?
It can be used in comparisons of frequency standards for searches of possible drifts in fundamental constants.