Highly efficient Raman fiber laser Collaborators: E. Bélanger M. Bernier B. Déry D. Faucher Réal Vallée.

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Presentation transcript:

Highly efficient Raman fiber laser Collaborators: E. Bélanger M. Bernier B. Déry D. Faucher Réal Vallée

OUTLINE I: Raman scattering and gain II: Raman fiber lasers (two generations) III: Standard Model IV: Experimental set-up V: Results & discussion VI: Conclusion

I: Raman fiber laser (RFL)

Raman scattering Spontaneous Stimulated

D.J. Dougherty, et al. Opt. Lett. 20, (1995) Raman gain = 1μm

Pump Stokes Evolution of the Stokes and pump signals : Forward SRS

2. Time-dispersion tuning: C. Lin et al. Appl. Phys. Lett. 31 (1977) CW 1. Angular tuning: Raman fiber lasers: 1 st generation R. Stolen et al. Appl. Phys. Lett. 30, (1977) 340

Raman fiber lasers: 2 nd generation  Key elements were developed for the 2 nd generation of RFL Fiber Bragg gratings providing reduced losses, spectral selectivity & tunability Low loss fibers standard or with high Ge or P content High power Ytterbium fiber lasers providing power, reliability and spectral bandwidth

Raman fiber lasers: 2 nd generation Nested cavities

Spectral coverage E.M. Dianov et al., Quantum Electron. 35, (2005)

PpPp PsfPsf PsbPsb P p IN P s OUT 0 L Z P p IN P s OUT R1R1 R2R2 1108nm 1165nm Bragg gratings Standard numerical model

 Boundary conditions: Standard numerical model  Propagation equations:

R IC = 99% Laser optimisation vs R OC

Laser optimisation vs L R IC = 99% R OC = 26%

II: Highly efficient FRL

(15 W) Corning HI980 (9% Ge) Experimental set-up

Pump Stokes

Parameters used in simulationOC1 configurationOC2 configuration Fiber attenuation p dB/km Fiber attenuation s dB/km Splicing losses0.03 dB IC gray losses0.04 dB IC cladding-mode s  eff OC gray losses0.01 dB OC cladding-mode s 0.00 dB IC reflectivity99.6 % OC reflectivityR eff /55 %R eff /26 %

Spectral broadening

First configuration: OC1

Laser curve with OC1

Stokes vs absorbed pump with OC1

Second configuration: OC2 IC OC2

Laser curve with OC2

Stokes vs absorbed pump with OC2

Effective reflectivity

Effective reflectivity (OC2)

Cladding-mode losses (IC)

Effective losses (IC/OC2)

Laser curve with OC2

Tuning of FBGs : Set-up

Tuning curve

Conclusion  RFL with efficiencies approaching quantum limit can be obtained using well designed FBGs.  The standard model (AuYeung & Yariv) can be used provided effective R and  are considered.  10 W output is achievable from an optical fiber with a moderate Ge content.  Tunability over tens of nm is expected.