E. A. Peganov, S. N. Smetanin, N. A. Karpov, V. I. Samoilov, I. S. Makogon, P. D. Kharitonova, A. N. Boyko, I. A. Zuikov, L. I. Ivleva, “Simulation of high-energy nanosecond Raman laser on a <nobr>$\mathrm{BaWO_4}$</nobr> crystal”, Kvantovaya Elektronika, 2025, Volume 55, Number 1,Pages <nobr>15

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Simulation of high-energy nanosecond Raman laser on a $\mathrm{BaWO_4}$ crystal

E. A. Peganov^ab, S. N. Smetanin^b, N. A. Karpov^ac, V. I. Samoilov^ac, I. S. Makogon^a, P. D. Kharitonova^b, A. N. Boyko^ad, I. A. Zuikov^ad, L. I. Ivleva^b

^a Troitsk Institute for Innovation and Fusion Research
^b Prokhorov General Physics Institute of the Russian Academy of Sciences, Moscow
^c National Engineering Physics Institute "MEPhI", Moscow
^d Peoples' Friendship University of Russia named after Patrice Lumumba, Moscow

Abstract: The operability of a wide-aperture barium tungstate ($\mathrm{BaWO_4}$) crystal as an active medium of a nanosecond laser on forced Raman scattering with a record high energy of 1 Joule output radiation pulses is investigated. The experiments have shown the high resistance of the $\mathrm{BaWO_4}$ crystal to laser pulses with a laser destruction threshold of 10 J/cm2. Mathematical modeling of a Raman laser when pumped with a neodymium glass laser (1053 nm, 6 J) showed an effective conversion of pumping energy into Stokes components with energies of 1.8 (1167 nm), 1.7 (1214 nm) and 0.8 J (1265 nm) in an optical resonator, the output mirror of which is the output end of the Raman crystal.

Keywords: stimulated Raman scattering, high-energy Raman laser, radiation resistance.

Received: 24.10.2024
Revised: 24.02.2025
Accepted: 24.02.2025