A theoretical study of transient stimulated Brillouin scattering in optical fibers seeded with phase-modulated light

Zeringue, Clint; Dajani, Iyad; Naderi, Shadi; Moore, Gerald; Robin, Craig

doi:10.1364/oe.20.021196

Cited by 134 publications

(81 citation statements)

References 12 publications

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“…The resulting tones of the phase modulator were spaced by 66.6 MHz; which is ~1.5x greater than the BG FWHM of the primary response. Zeringue et al argue in [9] that optimal SBS suppression for a given phase-broadened bandwidth is when the spacing of the phase modulator tones are 2-3 times greater than the BG FWHM. The bit pattern in this study is not optimal, but it will be shown that the PRBS scheme sufficiently suppressed SBS.…”

Section: Frequency (Ghz)mentioning

confidence: 99%

Power scaling of a hybrid microstructured Yb-doped fiber amplifier

et al. 2017

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Hybrid microstructured fibers, utilizing both air holes and high index cladding structures, provide important advantages over conventional fiber including robust fundamental mode operation with large core diameters (>30μm) and spectral filtering (i.e. amplified spontaneous emission and Raman suppression). This work investigates the capabilities of a hybrid fiber designed to suppress stimulated Brillouin scattering (SBS) and modal instability (MI) by characterizing these effects in a counter-pumped amplifier configuration as well as interrogating SBS using a pump-probe Brillouin gain spectrum (BGS) diagnostic suite. The fiber has a 35 μm annularly gain tailored core, the center doped with Yb and the second annulus comprised of un-doped fused silica, designed to optimize gain in the fundamental mode while limiting gain to higher order modes. A narrow-linewidth seed was amplified to an MI-limited 820 W, with near-diffraction-limited beam quality, an effective linewidth ~ 1 GHz, and a pump conversion efficiency of 78%. Via a BGS pump-probe measurement system a high resolution spectra and corresponding gain coefficient were obtained. The primary gain peak, corresponding to the Yb doped region of the core, occurred at 15.9 GHz and had a gain coefficient of 1.92×10-11 m/W. A much weaker BGS response, due to the pure silica annulus, occurred at 16.3 GHz. This result demonstrates the feasibility of power scaling hybrid microstructured fiber amplifiers

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Section: Frequency (Ghz)mentioning

confidence: 99%

Power scaling of a hybrid microstructured Yb-doped fiber amplifier

et al. 2017

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“…Equations (1)-(3) have been used to describe Brillouin scattering in a passive fiber without amplification [6] and with a nominal 10× gain [7]. To simulate an amplifier with realistic gain and gain saturation, (4) and (5) are included.…”

Section: Numerical Modelmentioning

confidence: 99%

Stimulated Brillouin Scattering Suppression With a Chirped Laser Seed: Comparison of Dynamical Model to Experimental Data

Petersen

Yang

Satyan

et al. 2013

IEEE J. Quantum Electron.

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A numerical model is developed to simulate stimulated Brillouin scattering (SBS) in high power single-mode fiber amplifiers. The time dependent model incorporates both laser and Stokes wave amplification and initiates the Brillouin scattering from thermal phonons. A frequency chirped laser is used as the seed to suppress SBS. Experiments with Yb-doped fiber amplifiers show good agreement with the modeling. Using experimentally determined parameters, the model is used to predict chirp requirements for multi-kilowatt amplifiers with tens of meters of delivery fiber. A comparison is made between a chirped seed source and random phase modulation for SBS suppression.

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“…With the modulation period set at much shorter times than the acoustic phonon lifetime or the light traverse time, large SBS suppression factors can be obtained. 5 Typically, white noise source 3 (WNS) and pseudorandom bit sequence 6,7 (PRBS) have been the prevalent phase modulation techniques for kW-class fiber amplifiers. Recently, in a direct comparison conducted at the kW-level in Yb-doped amplifiers, PRBS phase modulation was shown to provide superior SBS suppression to that provided by WNS.…”

Section: Introductionmentioning

confidence: 99%

Multi-kilowatt diffractive coherent combining of pseudorandom-modulated fiber amplifiers

et al. 2016

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Abstract. We report efficient coherent beam combining of five kW-class fiber amplifiers seeded with pseudorandom phase-modulated light, using a 1 × 5 diffractive optical element (DOE). Each fiber amplifier channel was path length matched, actively polarized, and provided approximately 1.2 kW of near diffraction-limited output power (M 2 < 1.1). A low-power sample of the combined beam after the DOE provided an error signal for active phase stabilization. After phase stabilization, the beams were coherently combined via the DOE. Notably, a total output power of ∼5 kW was achieved with 82% combining efficiency and excellent beam quality (M 2 < 1.1). The intrinsic DOE splitter loss was 5%. Additional losses due in part to nonideal polarization, amplified spontaneous emission content, uncorrelated wavefront errors, and fractional beam misalignments contributed to the efficiency reduction. Overall, multi-kW beam combining of pseudorandom-modulated fiber amplifiers was demonstrated for the first time.

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A theoretical study of transient stimulated Brillouin scattering in optical fibers seeded with phase-modulated light

Cited by 134 publications

References 12 publications

Power scaling of a hybrid microstructured Yb-doped fiber amplifier

Power scaling of a hybrid microstructured Yb-doped fiber amplifier

Stimulated Brillouin Scattering Suppression With a Chirped Laser Seed: Comparison of Dynamical Model to Experimental Data

Multi-kilowatt diffractive coherent combining of pseudorandom-modulated fiber amplifiers

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