Research output: Contribution to journal › Article › peer-review
Transverse mode distribution in multimode diode-pumped Raman fiber laser. / Sidelnikov, Oleg; Kuznetsov, Alexey; Kharenko, Denis et al.
In: Journal of the Optical Society of America B: Optical Physics, Vol. 40, No. 12, 12.2023, p. 3269-3275.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Transverse mode distribution in multimode diode-pumped Raman fiber laser
AU - Sidelnikov, Oleg
AU - Kuznetsov, Alexey
AU - Kharenko, Denis
AU - Gervaziev, Mikhail
AU - Podivilov, Evgeny
AU - Fedoruk, Mickhail
AU - Wabnitz, Stefan
AU - Babin, Sergey
N1 - This work is supported by grants from the RSF (20-11-20040, work of M.P.F. and O.S.S.), the RSF (21-42-00019, work of A.G.K., D.S.K, M.D.G., E.V.P., S.A.B), and the European Union under the Italian National Recovery and Resilience Plan (NRRP) of NextGenerationEU, in partnership with “Telecommunications of the Future” (PE00000001—program “RESTART”) (work of S.W.).
PY - 2023/12
Y1 - 2023/12
N2 - Raman lasers based on multimode graded-index fibers may generate high-quality (M2 ∼ 2) Stokes beams when pumped by highly multimode (M2 > 30) laser diodes. Here we, examine, both experimentally and theoretically, the energy distribution of the output Stokes beam across the principal quantum mode number n in a bent multimode fiber operating well above the Raman threshold. In contrast to Kerr spatial beam cleaning, leading to a Rayleigh–Jeans mode power distribution, in a multimode Raman fiber laser, we find that the output mode powers approach an exponential distribution. We introduce a coupled-mode equations model, including random linear coupling between neighboring mode groups, and obtain a good agreement between numerical simulations and experimental results. The model shows that, for typical mode coupling coefficients, the randomization of the mode power distribution is compensated by both nonlinear (Raman and Kerr) effects and linear filtering from the fs-inscribed fiber Bragg grating, both acting on the Stokes beam over successive round trips. When random coupling becomes the dominating factor, the mode power distribution of the Stokes beam tends to equipartition, similar to what is observed with large-size highly multimode beams of low intensity (and nonlinearity) in the absence of any filtering.
AB - Raman lasers based on multimode graded-index fibers may generate high-quality (M2 ∼ 2) Stokes beams when pumped by highly multimode (M2 > 30) laser diodes. Here we, examine, both experimentally and theoretically, the energy distribution of the output Stokes beam across the principal quantum mode number n in a bent multimode fiber operating well above the Raman threshold. In contrast to Kerr spatial beam cleaning, leading to a Rayleigh–Jeans mode power distribution, in a multimode Raman fiber laser, we find that the output mode powers approach an exponential distribution. We introduce a coupled-mode equations model, including random linear coupling between neighboring mode groups, and obtain a good agreement between numerical simulations and experimental results. The model shows that, for typical mode coupling coefficients, the randomization of the mode power distribution is compensated by both nonlinear (Raman and Kerr) effects and linear filtering from the fs-inscribed fiber Bragg grating, both acting on the Stokes beam over successive round trips. When random coupling becomes the dominating factor, the mode power distribution of the Stokes beam tends to equipartition, similar to what is observed with large-size highly multimode beams of low intensity (and nonlinearity) in the absence of any filtering.
UR - https://www.scopus.com/record/display.uri?eid=2-s2.0-85179841657&origin=inward&txGid=486232ea1dc690c98b8a7621fddc3e12
UR - https://www.mendeley.com/catalogue/f3248d30-dc92-3add-90a7-4bbbdc9d5845/
U2 - 10.1364/josab.503609
DO - 10.1364/josab.503609
M3 - Article
VL - 40
SP - 3269
EP - 3275
JO - Journal of the Optical Society of America B: Optical Physics
JF - Journal of the Optical Society of America B: Optical Physics
SN - 0740-3224
IS - 12
ER -
ID: 59390896