Kvantovaya Elektronika
RUS  ENG    JOURNALS   PEOPLE   ORGANISATIONS   CONFERENCES   SEMINARS   VIDEO LIBRARY   PACKAGE AMSBIB  
General information
Latest issue
Archive
Impact factor
Submit a manuscript

Search papers
Search references

RSS
Latest issue
Current issues
Archive issues
What is RSS


Kvantovaya Elektronika:
Year:
Volume:
Issue:
Page:
Find




Personal entry:
Login:
Password:
Save password
Enter
Forgotten password?
Register

Kvantovaya Elektronika, 2020, Volume 50, Number 5, Pages 475–488 (Mi qe17247)  
This article is cited in 11 scientific papers (total in 11 papers)

Invited paper

Photonic methods and technologies for monitoring the ocean and atmosphere

Yu. N. Kulchinab, S. S. Voznesenskiia, E. L. Gamayunova, S. S. Golikab, A. A. Il'ina, O. T. Kamenevab, A. I. Nikitina, A. N. Pavlova, A. Yu. Popika, R. V. Romashkoab, E. P. Subbotina

a Institute for Automation and Control Processes, Far Eastern Branch of the Russian Academy of Sciences, Vladivostok
b Far Eastern Federal University, Vladivostok
Full-text PDF (23680 kB) Citations (11)
References:
PDF
HTML
Abstract: In this paper, we review photonic methods and technologies that are promising for monitoring the ocean and atmosphere and have been implemented mainly in recent years at the Institute of Automation and Control Processes, Far Eastern Branch, Russian Academy of Sciences. We present results of lidar studies that have made it possible to understand key features of ocean–atmosphere interaction processes under continent–ocean transition conditions, which determine specific features of the atmospheric aerosol distribution, small gaseous components of the atmosphere and its optical characteristics. We consider methods and tools for combined optical and laser fluorescence monitoring of the ocean surface. Particular attention is paid to results of research on remote methods and tools for real-time laser spark and laser fluorescence environmental monitoring of the ocean, including specialised fibre-optic probes and mobile underwater robotic systems. We present results of the development and investigation of highly sensitive, noise-proof fibre-optic hydro- and seismic/acoustic sensors for remote monitoring of the ocean and robotic systems for underwater laser protection of marine vessels, hydraulic structures and oceanographic instruments against the negative impact of biofouling.
Keywords: lidar, atmosphere, ocean, monitoring, spectrum, laserinduced fluorescence, laser spark spectroscopy, biofouling.
Funding agency Grant number
Far Eastern Branch of the Russian Academy of Sciences 18-3-044
18-5-080
Ministry of Education and Science of the Russian Federation 0657-2020-0003
Russian Science Foundation 19-12-00323
Russian Foundation for Basic Research 16-29-02082 офи_м
16-05-0750 а
Received: 28.11.2019
Revised: 14.03.2020
English version:
Quantum Electronics, 2020, Volume 50, Issue 5, Pages 475–488
DOI: https://doi.org/10.1070/QEL17222
Bibliographic databases:
Document Type: Article
Language: Russian
Supplementary materials:
pic_12.pdf (5.8 Mb)
pic_13.pdf (8.2 Mb)


Citation: Yu. N. Kulchin, S. S. Voznesenskii, E. L. Gamayunov, S. S. Golik, A. A. Il'in, 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”, Kvantovaya Elektronika, 50:5 (2020), 475–488 [Quantum Electron., 50:5 (2020), 475–488]
Linking options:
  • https://www.mathnet.ru/eng/qe17247
  • https://www.mathnet.ru/eng/qe/v50/i5/p475
    • This publication is cited in the following 11 articles:
    1. Yu.N. Kulchin, G.I. Dolgikh, R.V. Romashko, A.L. Sobisevich, O.T. Kamenev, Russian Geology and Geophysics, 2025  crossref
    2. Yu. E. Geints, O. V. Minina, Atmos Ocean Opt, 37:2 (2024), 183  crossref
    3. Grigory Dolgikh, Sergey Budrin, Stanislav Dolgikh, Mikhail Bolsunovskii, Mikhail Ivanov, Sensors, 25:1 (2024), 48  crossref
    4. Qing Liu, Liye Peng, Kang Shang, Nonlinear Engineering, 12:1 (2023)  crossref
    5. M. R. Zaripov, V. A. Alekseev, A. I. Kirillov, A. V. Oficerova, Prib. metody izmer., 14:1 (2023), 44  crossref
    6. Romashko V R. Storozhenko V D. Bezruk M.N. Bobruyko D.A. Kulchin Y.N., Laser Phys., 32:2 (2022), 025101  crossref  isi  scopus
    7. A. Yu. Mayor, S. S. Golik, Yu. S. Tolstonogova, A. A. Ilyin, O. A. Bukin, Atmos Ocean Opt, 35:5 (2022), 497  crossref
    8. Sridarshini T., Preethi Chidambaram, Geerthana S., Balaji V.R., Arun Thirumurugan, Sitharthan, Karthikeyan Madurakavi, Shanmuga Sundar Dhanabalan, Sustainable Computing: Informatics and Systems, 36 (2022), 100815  crossref
    9. Quantum Electron., 51:3 (2021), 265–271  mathnet  crossref  isi  elib
    10. O. T. Kamenev, Yu. S. Petrov, A. A. Podlesnykh, V. A. Kolchinskiy, I. N. Zavestovskaya, Yu. N. Kulchin, R. V. Romashko, Bull. Lebedev Phys. Inst., 48:5 (2021), 135–138  crossref  isi
    11. S. N. Bagayev, S. M. Arakelian, A. O. Kucherik, D. N. Bukharov, O. Ya. Butkovsky, Bull. Russ. Acad. Sci. Phys., 84:12 (2020), 1427  crossref
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
    		Квантовая электроника Quantum Electronics
    Statistics & downloads:
    Abstract page:413
    Full-text PDF :81
    References:42
    First page:21
     
      Contact us:
    math-net2025_04@mi-ras.ru     		 Terms of Use  Registration to the website  Logotypes © Steklov Mathematical Institute RAS, 2025