Abstract
We present a comprehensive analysis of the technique of Longitudinal-Mode-Filling (LMF) to reduce Stimulated Brillouin Scattering (SBS) limitations in Ytterbium Doped Fibre Amplifiers (YDFA), for the generation of nanosecond, temporally shaped pulses. A basic Master-Oscillator-Power-Amplifier (MOPA) system, comprising an output YDFA with 10 µm-core active fibre, is experienced for benchmarking purposes. Input pulse-shaping is operated thanks to direct current modulation in highly multimode laser-diode seeds, either based on the use of Distributed Feed-Back (DFB) or of a Fibre Bragg Grating (FBG). These seeds enable wavelength control. We verify the effectiveness of the combination of LMF, with appropriate mode spacing, in combination with natural chirp effects from the seed to control the SBS threshold in a broad range of output energies, from a few to some tens of µJ. These variations are discussed versus all the parameters of the laser system. In accordance with the proposal of a couple of basic principles and with the addition of gain saturation effects along the active fibre, we develop a full-vectorial numerical model. Fine fits between experimental results and theoretical expectations are demonstrated. The only limitation of the technique arises from broadband beating noise, which is analysed thanks to a simplified, but fully representative description to discuss the signal-to-noise ratio of the amplified pulses. This provides efficient tools for application to the design of robust and cost-effective MOPAs, aiming to the generation of finely shaped and energetic nanosecond pulses without the need for any additional electro-optics.
Highlights
The well-known phenomena of Stimulated-Brillouin-Scattering (SBS) takes place among the most deleterious limitations for the production of high energies [1,2,3,4] using all-fiber MasterOscillator-Power-Amplifiers (MOPA)
We present a comprehensive analysis of the technique of Longitudinal-Mode-Filling (LMF) to reduce Stimulated Brillouin Scattering (SBS) limitations in Ytterbium Doped Fibre Amplifiers (YDFA), for the generation of nanosecond, temporally shaped pulses
We reviewed the major topics of interest for SBS-free MOPAs, when seeded by means of shaped, highly multimode LD-seeds operated in the regime of direct current modulation
Summary
The well-known phenomena of Stimulated-Brillouin-Scattering (SBS) takes place among the most deleterious limitations for the production of high energies [1,2,3,4] using all-fiber MasterOscillator-Power-Amplifiers (MOPA). Modulations occur in a broad band of frequencies, which depends on the spacing between adjacent longitudinal modes and on the number of modes contained in the spectrum of the seed This is the reason why properly controlled LMF requires the management of a basic tradeoff, between the enhancement of threshold for the onset of SBS and the specification of a given measurement bandwidth (MB), for efficient output pulse-shaping. We develop a fully numerical process dedicated to the calculation of the Optical Signal-To-Noise-Ratio (OSNR) in the presence of multimodal beating noise effects, as a function of the characteristics of DBF and FBG seeds This will help to optimize seed options regarding the above tradeoff between the SBS limitations and beating noise, to ensure the generation of smooth pulse profiles within a given MB
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