MEASURING SEA ICE THICKNESS WITH THE LOZA GEORADAR
Abstract and keywords
Abstract (English):
This article documents the use of portable georadar for measuring the thickness of sea ice. This device was developed to replace the method for measuring ice thickness by drilling ice holes. The device based on the use of the LOZA georadar (ground penetrating radar, GPR) and a specially developed method of field measurements when landing on the studied ice formations. The study of the thickness and structure of sea ice by radar method is a complex problem. The salinity of sea ice determines its significant conductivity, which, in turn, causes a large attenuation of the electromagnetic signal of the georadar. The widespread GPR with a pulse power of 50-100 W are not applicable for sounding sea ice precisely because of the large signal attenuation. The LOZA instrument is equipped with a transmitter with a pulse power of 1 MW. This is, on average, 10,000 times greater than that of "traditional" GPRs. Multiple measurements of the thickness of ice formations, carried out on the one-year ice of the eastern shelf of Sakhalin Island during winter expeditions of 2016 and 2019, have shown that the device can quickly, accurately and with a high spatial resolution measure the thickness of both flat and highly deformed ice (hummocks, rafted ice, and rubble field) over large areas.

Keywords:
Sea ice thickness, ice formations, georadar, GPR
Text
Publication text (PDF): Read Download
References

1. Berkut, A. I., D. E. Edemsky, V. V. Kopeikin, et al. (2017) , Deep penetration subsurface radar: hardware, results, interpretation, Proc. 9th Int. Symp. on Advanced Ground Penetrat. Radar (IWAGPR), PS-2, p. 3-25, IEEE, Edinbourgh, UK, https://doi.org/10.1109/IWAGPR.2017.7996052

2. Eicken, H., W. B. Tucker III, D. K. Perovich (2001) , Indirect measurements of the mass balance of summer Arctic sea ice with an electromagnetic induction technique, Annals of Glaciology, 33, p. 194-200, https://doi.org/10.3189/172756401781818356

3. Finkelstein, M. I., E. I. Lazarev, A. N. Chizhov (1984) , Radar Aerial Ice Surveys of Rivers, Lakes, Reservoirs, 112 pp., Gidrometeoizdat, Leningrad (in Russian)

4. Haas, C., S. Gerland, H. Eicken, H. Miller (1997) , Comparisono of sea-ice thickness measurements under summer and winter conditions in the Arctic using a small electromagnetic induction device, Geophysics, 62, p. 749-757, https://doi.org/10.1190/1.1444184

5. GOST R 58283-2018, (2018) , National Standard of the Russian Federation. Oil and Gas Industry Arctic Operations. Consideration of Ice Loads in the Design of Offshore Platforms, 36 pp., Standartinform, Moscow (in Russian)

6. Kovacs, A., R. M. Morey (1991) , Sounding sea-ice thickness using a portable electromagnetic induction instrument, Geophysics, 56, p. 1992-1998, https://doi.org/10.1190/1.1443011

7. LLC "Logical Systems", (2013) , Radio-Technical Device for Subsurface Sounding (Georadar) "OKO-2", Technical Description and User's Manual, 98 pp., Ramenskoye, Moscow region (in Russian)

8. Marchenko, A. V., E. G. Morozov (2016) , Surface manifestations of the waves in the ocean covered with ice, Russ. J. Earth Sci., 16, p. ES1001, https://doi.org/10.2205/2016ES000561

9. Mironov, E. U., Yu. P. Gudoshnikov, V. N. Smirnov (2015) , Modern methods of ice research and surveys on the shelf of the Arctic seas, Problems of the Arctic and Antarctic, no. 1 (103), p. 57-68 (in Russian)

10. Pisarev, S. V. (2016) , Winter expeditionary research in the water area of the Yuzhno-Kirinskoye field in 2016, Russian Polar Research, 3, no. 25, p. 8-11 (in Russian)

11. Sokolov, V. T., S. V. Kochetov, N. V. Lebedev, et al. (2007) , Climatic Fields of Thermohaline Characteristics of the Laptev Sea, Electronic Reference Manual, AARI, St. Petersburg (in Russian)

12. Uvarov, U. (2013) , Pikor-Ice: Russian UWB technology, First Mile, 6, p. 60-62 (in Russian)

Login or Create
* Forgot password?