ИАПУ ДВО РАН

Golik Sergey Sergeevich

Degree: PhD (Phys.-Math.)

Title: lecture

Position: senior scientific employee

Department: Лаборатория лазерных методов исследования вещества (№23)

Room: 236

Phone:

Internal Phone: 2-72

Email: golik_s@iacp.dvo.ru

Publications:

Article

2012.
2017.
2020. Yu.N.Kulchin, S.S.Voznesensky, E.L.Gamayunov, S.S.Golik, A.A.Ilyin, O.T.Kamenev, A.I.Nikitin, A.N.Pavlov, A.Yu.Popik, R.V.Romashko, E.P.Subbotin, "Photonic methods and technologies for monitoring the ocean and atmosphere", QUANTUM ELECTRON, 2020, 50 (5), 475–488
2017. Ilyin, A.A., Golik, S.S., Babiy, M.Y., Biryukova, Y.S., Lisitsa, V.V., Burov, D.V., Kulchin, Y.N. Spectral and temporal characteristics of Ba I emission in femtosecond laser-induced breakdown on the surfaces of aqueous solutions // Technical Physics Letters. 2017. Vol.43. Is.9. P.860-862.
2013. Ilyin, A.A., Golik, S.S. Femtosecond laser-induced breakdown spectroscopy of sea water // Spectrochimica Acta Part B Atomic Spectroscopy Vol. 87, p. 192-197 · June 2013 DOI: 10.1016/j.sab.2013.06.001
2013.
2015. S.S. Golik, A.A. Ilyin, M.Yu. Babiy, Yu.S. Biryukova, T.M. Agapova, A.Yu. Mayor, O.A. Bukin, Yu.N. Kulchin, The influence of laser pulse repetition rate on the intensity of spectral lines in femtosecond laser-induced breakdown spectroscopy of a liquid // Technical Physics Letters, 2015, vol. 41 (11), p.1044-1046
2014.
2012.
2018. A.A. Ilyin, S.S. Golik, K.A. Shmirko, A.Yu. Mayor, D.Yu. Proschenko and Yu.N. Kulchin, Broadening and shift of emission lines in a plasma of filaments generated by a tightly focused femtosecond laser pulse in air, Quantum Electronics, 2018, 48:2, 149–156
2016.
2015. The influence of the energy of femtosecond laser pulses on the intensity of Fe I (371.99 nm) emission line and the continuous spectrum of the plasma generated on the surface of Fe3+ water solution by a Ti: sapphire laser radiation with pulse duration < 45 fs and energies up to 7 mJ is determined. A calibration curve was obtained for Fe3+ concentration range from 0.5 g/L to the limit of detection in water solution, and its saturation was detected for concentrations above 0.25 g/L, which is ascribed to self-absorption. The 3σ- limit of detection obtained for Fe in water solution is 2.6 mg/L in the case of 7 mJ laser pulse energy. It is found that an increase of laser pulse energy insignificantly affects on LOD in the time-resolved LIBS and leads to a slight improvement of the limit of detection.