The iceberg drift study near Severnaya Zemlya in the spring of 2018 by remote sensing data

The movement of icebergs in the Laptev Sea off the coast of the Severnaya Zemlya archipelago in spring of 2018 was analyzed using satellite observations in visible spectral band. As is shown in the article the data of radiometers installed on the Landsat-8 and Sentinel-2 satellites allow monitoring of iceberg drifting in spring period in the above Arctic region. Thus, in March-April 2018, the total amount of icebergs detected near the archipelago was 4917. 4161 icebergs were in the landfast ice, 722 ones were drifting with the ice fields, and the other 32 were aground in ice fields. The average length of the icebergs was equal to 88 m; the largest of the recognized icebergs was located in the landfast ice near the ice shelf of the Matusevich fjord and it was 1240 m in length. The maximum speed of drift of the icebergs, as determined by the satellite data, was equal to 29.5 km/day. This was estimated for the situation when the speed of the near-water (surface) wind reached 20 m/s and larger. The purpose of the work was to study drifting of icebergs in order to define more exactly dynamics of the iceberg movement in this poorly known area of the Arctic. It is found that in a case of the consolidated ice cover the drift speed of ice fields with the icebergs involved depends on the driving wind force and direction. According to mean speeds of movement all icebergs were separated into three groups: the icebergs of the coastal zone with velocities smaller 1 km/day; the icebergs of the transition zone at speeds of 1.3 to 1.6 km/day; and the icebergs of the transit zone with speeds larger 2 km/day. The characteristics of the iceberg drifts obtained on the basis of daily satellite monitoring can be used in regional iceberg drift models to ensure safe economic activity on the Arctic shelf. Also, they can find application in engineering calculations in the design of infrastructure facilities on the shelf of the Arctic seas.

1. BychkovaI.A., Smirnov V.G. Use of space information for iceberg detection and iceberg threat assessment Led i Sneg. Ice and Snow. 2018, 4: 537- 551. [In Russian],

2. Kulakov M.Yu., Demchev D.M. Simulation of Iceberg Drift as a Part of Ice Monitoring in the West Arctic . Meteorologiya i Gidrologiya. Meteorology and Hydrology. 2015, 12: 47-55. [In Russian],

3. Mironov E.U., Smirnov V.G., Bychkova I.A., Kulakov M. Yu., Demchev D.M. New technologies for detecting icebergs and predicting their drift in the Western sector of Arctic. Problemy Arktiki i Antarktiki. Arctic and Antarctic Problems . 2015, 2 (104): 21-32. [In Russian],

4. Obnaruzhenie po sputnikovym dannym opasnykh ledyanykh obrazovaniy vblizi inzgenernykh ob’ektov kho-zyaistvennoy deyatelnosti na shelfe arkticheskikh morey. Detection of dangerous ice features near the arctic shelf engineering constructions with the use of satellite imagery: A methodical manual. Ed. by V G . Smirnov. St . Petersburg: AARI, 2017: 76 p . [In Russian],

5. Sputnikovye metody opredeleniya kharakteristik ledyanogo pokrova morey. Satellite methods to determine the characteristics of the ice cover of the seas . Ed. by V G . Smirnov. St. Petersburg: AARI, 2011: 239 p . [In Russian],

6. Buzin I.V., Mironov E.U., Sukhikh N.A., Pavlov V.A., Kornishin К.А., Efimov Ya.O. Study of ice drift features on the Russian Arctic Offshore with the help of automatic radio beacons based on the ARGOS satellite system Nauchno-tekhmcheskU vestnik ОАО «NK «Rosneft». Rosneft Oil Company Journ . of Science and Technology. 2016, 45 (4): 4-9. [In Russian],

7. Janout M.A., Holemann J., Timokhov L., Gutjahr O., Heinemann G. Circulation in the northwest Laptev Sea in the eastern Arctic Ocean: crossroads between Siberian river water, Atlantic water and polynya formed dense water // Journ. of Geophys . Research. Oceans . 2017, 122: 6630-6647. doi: 10.1002/2017JC013159 .

8. Karklin V.P., Karelin I.D. Seasonal and long-term variability of the ice conditions in the Laptev and East-Si-berian Seas . Systema morya Laptevykh iprilegayushchikh morey Arktiki: Sovremennoe sostoyanie i istoriya razvitiya. System of the Laptev Sea and the Adjacent Arctic Seas: Modern and Past Environments. Moscow: Moscow University Press, 2009: 187-201. [In Russian],

9. Janout M., Holemann J., Krumpen T. Cross-shelf transport of warm and saline water in response to sea ice drift on the Laptev Sea shelf. Journ . of Geophys . Research. Oceans . 2013, 118 (2): 563-576 . doi: 10.1029/2011JC007731.

10. Eik К. Iceberg drift modelling and validation of applied metocean hindcast Cold Regions Science and Technology. 2009, 57 (2/3): 67-90.

11. Selyuzhenok V., Mahoney A., Krumpen T., Castellani G., Gerdes R. Mechanisms of fast-ice development in the south-eastern Laptev Sea: a case study for winter of 2007/08 and 2009/10 . Polar Research . 2017, 36 (1): 1411140 . doi: 10.1080/17518369.2017.1411140.