GEOELECTRICAL SECTION OF THE BARGUZIN BAY OF LAKE BAIKAL ACCORDING TO GEORADAR AND RADIO IMPEDANCE SOUNDING DATA

Electrical resistivity (electrical conductivity) of water and bottom soil of the Barguzin Bay was studied by radio impedance soundings in VLF/LF bands, and the measurements were analysed. The georadar sounding method was used to investigate dielectric permittivity of freshwater ice (dielectric constant is ε=3.4). We developed the technique of radio impedance sounding from the ice surface of Lake Baikal for measuring the electrical resistance of bottom soil in the water area, and applied this technique to a layered model of a medium with a base showing poor/good conductivity. Geoelectric models were constructed for the Barguzin Bay coast and the southern Lake Baikal. The geoelectrical section (GES) of the water area can be useful for earthquake forecasting from electromagnetic data, as well as for analysing the physical and chemical causes of the occurrence of ring structures on the ice surface of Lake Baikal.

GPR, radio impedance sounding, geoelectrical section (GES), Lake Baikal, Barguzin Bay

1. Afraimovich E.L., Zherebtsov G.A., Perevalova N.P., Sankov V.A., Bashkuev Yu.B., Kurkin V.I., Kovalenko V.A., Rakhmatulin R.A., Mikhalev A.V., Berngardt O.I. et al., 2012. Seismoionospheric and Seismoelectromagnetic Processes in the Baikal Rift Zone. SB RAS Publishing House, Novosibirsk, 304 p. (in Russian)

2. Angarkhaeva L.Kh., 2002. The Impedance Software Package for Solving Problems of Radio Impedance Sounding. Certificate of Official Registration of Computer Program № 2002610893 Dated June 06, 2002. The Impedance Software Package for Solving Problems of Radio Impedance Sounding. ROSPATENT, Moscow (in Russian)

3. Balkhanov V.K., Bashkuev Y.B., 2011. Way of Detecting an Electromagnetic Earthquake Precursor. Technical Physics 56, 1359. http://dx.doi.org/10.1134/S1063784211090040.

4. Balkhanov V.K., Bashkuev Y.B., 2013. On the Appearance of a Convective Toroidal Vortex in Lake Baikal. Technical Physics 58, 1582–1586. http://dx.doi.org/10.1134/S1063784213110054.

5. Balkhanov V.K., Bashkuev Y.B., Khaptanov V.B., 2010. Formation of Circular Rings on the Snow-Covered Ice Field of Lake Baikal. Technical Physics 55, 1266–1269. http://dx.doi.org/10.1134/s1063784210090057.

6. Bashkuev Y.B., 1996. Electrical Properties of Natural Layered Media. SB RAS Publishing House, Novosibirsk, 207 p. (in Russian)

7. Bashkuev Yu.B., Advocatov V.R., Khaptanov V.B., Buyanova D.G., Angarkhaeva L.Kh., 1993. Electromagnetic Characteristics of the Lake Baikal Water Area. Geology and Geophysics 9, 118–126 (in Russian)

8. Bashkuev Yu.B., Khaptanov V.B., Buyanova D.G., Angarkhaeva L.Kh., Dembelov M.G., 2017. Geoelectric Characteristics of the Coastal Zone of Middle Baikal According to VLF/LF Radio Impedance Soundings. Journal of Radio Electronics 5 (in Russian) http://jre.cplire.ru/jre/may17/10/text.pdf.

9. Bashkuev Yu.B., Khaptanov V.B., Dembelov M.G., Angarkhaeva L.Kh., Boloev V.P., Hayakawa M., 2006. Radioprobing of Underground Structure of the Failure Gulf, Formed as a Result of the M7.5 Tsagan Earthquake. Physics and Chemistry of the Earth 31 (4–9), 210–214. http://dx.doi.org/10.1016/j.pce.2006.02.030.

10. Budnev N.M., 2011. A Laboratory in Baikal Waters. Priroda 12, 11–22 (in Russian) https://priroda.ras.ru/pdf/2011-12.pdf.

11. Efremov V.N., 2013. Radio Impedance Sounding of Frozen Soils. Permafrost Institute SB RAS, Yakutsk, 204 p. (in Russian)

12. GeoScan32, 2013. Illustrated User Guide. LOGIS, Ramenskoye, 132 p. (in Russian) http://www.geotech.ru/files/Oko20130718GeoSc32Man.pdf.

13. Ireland G.C., 1961. A Provisional Ground Conductivity Map of Canada. Proceedings of the IRE 49 (11), 1674–1678. https://doi.org/10.1109/JRPROC.1961.287793.

14. Jol H.M. (Ed.), 2009. Ground Penetrating Radar: Theory and Applications. Elsevier Science, Oxford, 508 p.

15. Korotaev S.M., Serdyuk V.O., Shneer V.S., Machinin V.A., Kiktenko E.O., Budnev N.M., Zurbanov V.L., Mirgazov R.R., Buzin V.B., Panfilov A.I., 2015. Recent Results of Monitoring of the Vertical Component of the Electrical Field in Lake Baikal on the Surface-Bed Baseline. Geomagnetism and Aeronomy 55, 398–409. http://dx.doi.org/10.1134/S0016793215020115.

16. Mel’chinov V.P., Bashkuev Yu.B., Angarkhaeva L.Kh., Buyanova D.G., 2006. Electrical Properties of the Cryolithozone of Eastern Russia in the Radio Band. Buryatia Scientific Center SB RAS, Ulan-Ude, 257 p. (in Russian)

17. OKO-2 Radio-Technical Device of Subsurface Sounding, 2006. Technical Description. User Manual. Logic Systems, Moscow, 101 p. (in Russian)

18. Semeikin N.P., Pomozov V.V., Dudnik A.V., 2005. Development of OKO Georadars. In: A.Yu. Grinev (Ed.), Problems of Subsurface Radiolocation. Radiotekhnika, Moscow, 231–236 (in Russian)

19. Shneer V.S., Trofimov I.L., Korotaev S.M., Gaidash S.P., Kuznetsova T.V., Tsirulnic L.B., Panfilov A.I., Budnev N.M., Mirgazov R.R., 2007. Long-Term Observations of the Electric Field Vertical Component in Lake Baikal (Preliminary Results). Izvestiya. Physics of the Solid Earth 43 (3), 331–335. https://doi.org/10.1134/S106935130704012X.

20. Tezkan B., Saraev A., 2008. A New Broadband Radiomagnetotelluric Instrument: Applications to near Surface Investigations. Near Surface Geophysics 6 (4), 245–252.

21. Tulokhonov A.K., Garmaev E.Z., Bashkuev Y.B., Lomukhin Y.L., Khaptanov V.B., Dembelov M.G., Slipenchuk M.V., Dorzhiev B.C., Ochirov O.N., 2018. Radiophysical Monitoring of the Lake Baikal Ice Cover. Geography and Nature Resources 39, 39–45. https://doi.org/10.1134/S1875372818010067.

22. Vladov M.L., Starovoitov A.V., 2004. Introduction to GPR. MSU Publishing House, Moscow, 153 p. (in Russian)