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High power ultrafast fiber amplifiers Yoann Zaouter, E. Cormier CELIA, UMR 5107 CNRS - Université de Bordeaux 1, France Stephane Gueguen, C. Hönninger,

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Presentation on theme: "High power ultrafast fiber amplifiers Yoann Zaouter, E. Cormier CELIA, UMR 5107 CNRS - Université de Bordeaux 1, France Stephane Gueguen, C. Hönninger,"— Presentation transcript:

1 High power ultrafast fiber amplifiers Yoann Zaouter, E. Cormier CELIA, UMR 5107 CNRS - Université de Bordeaux 1, France Stephane Gueguen, C. Hönninger, E. Mottay Amplitude Systèmes Pessac, France yzaouter@amplitude-systemes.com

2 Interests of Yb-doped fibers as amplifier medium –Interests of fibers –Interests of Ytterbium –High power double-clad fiber concept –Limitations New design of Yb-doped fibers –Microstructured fibers –Recent results Suggestion of design –Including Bulk and Fiber lasers The bright future of high power high energy fiber amplifiers Outline of the talk

3 Interests of fibers Numerous advantages –Reduced –Reduced free-space propagation –No –No thermo-optical problems –Excellent –Excellent beam quality: M 2 < 1.2 –High –High gain –Large –Large variety of dopants –Efficient –Efficient diode pumping operation Yb 3+ Er 3+ Nd 3+ Er 3+ Ho 3+ Er 3+ Tm 3+ Ho 3+ Pr 3+ Pr 3+ /Er 3+ /Ho 3+ /Tm 3+ 400 800 1200 1600 2000 2400 2800 [nm]

4 Interests of Ytterbium Very simple electronic structure of Yb ions –No –No undesired effects Weak quantum defect –Reduced –Reduced thermal load Diode pumping with 976nm diodes Broad emission bandwidth 2 F 7/2 2 F 5/2 975 nm 1,03 µm Crystal Field 2 F 5/2 Yb 3+ 2 F 7/2 N2N2 N1N1

5 Interests of Ytterbium-doped fibers Very simple electronic structure of Yb ions –No –No undesired effects Weak quantum defect –Reduced –Reduced thermal load Diode pumping with 976nm diodes Broad emission bandwidth

6 Interests of Ytterbium-doped fibers Very simple electronic structure of Yb ions –No –No undesire effects Weak quantum defect –Reduced –Reduced thermal load Diode pumping with 976nm diodes Broad emission bandwidth amplification Ideals candidates for the amplification of ultrashort pulses

7 Double-clad concept A highly efficient brightness conversion concept –Monomode signal core –Multimode inner-cladding for multimode diode pumping

8 Double-clad concept A highly efficient brightness conversion concept –Monomode signal core –Multimode inner-cladding for multimode diode pumping Pump Amplified signal Yb-doped active core Inner-claddingoutter-cladding

9 Double-clad concept A highly efficient brightness conversion concept –Monomode signal core –Multimode inner-clad for multimode diode pumping Pump Amplified signal Yb-doped active core Inner-claddingoutter-cladding Break the circular symmetry

10 Nonlinearity limitations Interaction length in fiber >> than in bulk –Nonlinearities are the limiting factors –Isotopic media lowest order nonlinearity:

11 Nonlinearity limitations 1.Nonlinear refraction index : –Self Phase Modulation : SPM Non linear phase shift : Instantaneous frequency :

12 Nonlinearity limitations 1.Nonlinear refraction index : –Self Phase Modulation : SPM Non linear phase shift : Instantaneous frequency : 2.Inelastic scatterings : –Stimulated Raman Scattering : SRS Frequency downshift through vibration of the medium: 13THz –Stimulated Brillouin Scattering : SBS Stokes shift of ~10GHz

13 Fighting Nonlinearities Reduced nonlinearities mean: –Smaller interaction length L –Larger mode field diameter A eff

14 Reduced nonlinearities mean: –Smaller interaction length L Dopants concentration –Larger mode field diameter A eff ! ! Multimode operation Fighting Nonlinearities

15 ! ! Multimode operation Diffraction-limited operation with larger core diameter Microstructured Fibers Reduced nonlinearities mean: –Smaller interaction length L Dopants concentration –Larger mode field diameter A eff

16 Microstrutured fibers 50 µm (NA = 0.03) Up to 50 µm core diameter with diffraction limited operation (NA = 0.03) Air-clad for pump propagation (NA = 0.6) Polarization maintaining design for environmentally stable operation

17 CPA-based amplification stage

18 Recent results (1/3) Laser Diode 40/170 Gold grating-based strectcher Transmission grating compressor OI 150 fs, 73 MHz F. Röser et al. Optics letters, 30, p2754, 2005

19 Recent results (1/3) Laser Diode 40/170 Gold grating-based strectcher Transmission grating compressor OI 150 fs, 73 MHz F. Röser et al. Optics letters, 30, p2754, 2005

20 Recent results (1/3) Laser Diode 40/170 Gold grating-based strectcher Transmission grating compressor OI 150 fs, 73 MHz F. Röser et al. Optics letters, 30, p2754, 2005

21 What if we want sub-100fs pulses ?

22 Recent results (2/3) Parabolic pulse amplification –Initialization of input energy and duration of the pulses –SpectrumDuration –Spectrum and Duration grow and converge to a parabolic shape during the propagation accumulating a purely linear chirp –Asymptotic solution of NLSE with gain –Easy to recompress with conventional grating-based compressor thanks to the linear chirp

23 Recent results (2/3) Parabolic pulse amplificationParabolic pulse amplification –EXEMPLE: –Oscillator: 400 fs, 75 MHz, 30 mW i.e. 400 pJ –Fiber amplifier: 9m, 23µm MFD, 0.7 m -1

24 Recent results (2/3) Parabolic pulse amplification –EXEMPLE: –Oscillator: 400 fs, 75 MHz, 30 mW i.e. 400 pJ –Fiber amplifier: 9m, 23µm MFD, 0.7 m -1

25 Recent results (2/3) Parabolic pulse amplification –EXEMPLE: – i.e assuming

26 Recent results (2/3) Parabolic pulse amplification –EXEMPLE: – i.e assuming –Experiment by Limpert et al. 180 fs, 75 MHz, 100 mW 9m Limpert et al., Optics Express, 10, p628, 2002 Oscillator Femtosecond oscillator

27 Recent results (2/3) Parabolic pulse amplification –Expériment of Limpert et al. Limpert et al., Optics Express, 10, p628, 2002

28 Recent results (2/3) Parabolic pulse amplification –Expériment of Limpert et al. Limpert et al., Optics Express, 10, p628, 2002

29 Energy scalable ?

30 Recent results (3/3) Nanosecond pulses amplification : –Aculight, Femlight –1 to 2 mJ, 1ns with 60 µm core-diameter fibers –>500 W/m power extraction reported by Femlight F. Salin et al. Optics Express, 14, p2275, 2006 C. D. Brooks et al. Optics Express, 13, p8999, 2005

31 Suggestion of design

32 Low power, long cavity oscillator –> 2 W average power –Rep rate of 10 MHz –< 400 fs pulse duration –Synchro-locked : adjusting the length of the cavity

33 PM - LMA fiber –Length and gain design for parabolic amplification –Polarization maintaining fiber OI Laser Diode PM - LMA fiber

34 Stretcher for CPA amplifier –Stretch the pulse to few hundreds of ps –Avoid nonlinearities in the power amplifier stage OI Laser Diode PM - LMA fiber Grating strectcher

35 < 1 m PM 40 µm core diameter microstructured fiber –Few tens of µJ @ 10 MHz –Pump-power-limited !! OI Laser Diode PM - LMA fiber Grating strectcher High Power Laser Diode PM – 40µm fiber

36 And hopefully … –~100 fs recompressed –Average power is pump-power-limited –Polarized and Synchro-Locked OI Laser Diode PM - LMA fiber Grating strectcher High Power Laser Diode PM – 40µm fiber

37 What’s coming up ? Fiber design 100 µm –Diffraction limited operation already demonstrated in a passive 100 µm core diameter microstructured fiber –New designs of PM microstructured fibers are on the run Energy and power improvement –10 mJ, 1ns –10 mJ, 1ns may (will ?) be achieved in the coming years –“Kilowatt Femto” is feasible

38 Thank you Visit our websites @: www.amplitude-systemes.com www.celia.u-bordeaux1.fr info@amplitude-systemes.com yzaouter@amplitude-systemes.com

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