Article information

2018 , Volume 23, ą 4, p.50-64

Kirbizhekova I.I., Chimitdorzhiev T.N., Dagurov P.N., Dmitriev A.V., Bykov M.E., Baltuhaev A.K., Dvornikov Y.A.

Monitoring of cryogenic processes of the Yamal Peninsula based on radar data TANDEM-X and ALOS-2 PALSAR-2

The article presents the results of the developed methods for thermal-degradation processes detection and monitoring based on the X- and L-bands radar data. The research objects are developing thermocircuits and collapsing slopes in the coastal zone of ten lakes of “Vaskiny Dachi” polygon (Central Yamal, 70∘15′N, 69∘05′E). To detect the formed and active cryogenic formations TanDEM-X and ALOS-2 PALSAR-2 interferometric and polarimetric data (VV, VH) of 2015-2016 were used.

The research was carried out in three directions: 1) digital terrain models (DTM) with high resolution construction using differential interferometry methods and the cryogenic formations topographical features identification, temporal changes in DTMs observation; 2) comparative statistical analysis of the total intensity and the polarimetric Í-Ŕ-α -decomposition components for cryogenic formations and adjacent stable sites; 3) development of a technique for express detection of such formations on the basis of total intensity and polarimetric Í-Ŕ-α -decomposition components images texture.

It is established that the intensity, polarimetric characteristics, topography parameters and textures of radar images significantly differ from those for neighbouring stable regions (more than 3 σ ) for active thermocircuits. Intensity variations are most significant, but the localization of cryogenic formations can be limited by the radar survey geometric conditions. For passive thermocircuits, landslides in the coastal zone, deviation of intensity and polarimetric characteristics from background ∼ σ , therefore as an indicator a set of polarimetric Í-Ŕ-α -decomposition parameters should be used. Combining parameters α and H can be the basis for express diagnostics of the occurrence and activation of cryogenic processes in the area of the present study.

[full text]
Keywords: satellite radar, polarimetric decomposition, differential interferometry, TanDEM-X, ALOS-2 PALSAR-2, cryomorphogenesis

doi: 10.25743/ICT.2018.23.16490

Author(s):
Kirbizhekova Irina Ivanovna
PhD. , Associate Professor
Office: Institute of Physical Material Science of the SB RAS
Address: 670047, Russia, Ulan-Ude, 6, Sakhyanovoy str.
Phone Office: (3012) 434819
E-mail: kirbizhekova@bk.ru
SPIN-code: 2463-0726

Chimitdorzhiev Tumen Namzhilovich
Dr. , Professor
Position: Head of Sector
Office: Institute of Physical Material Science of the SB RAS
Address: 670047, Russia, Ulan-Ude, 6, Sakhyanovoy str.
Phone Office: (3012) 416981
E-mail: tchimit@ipms.bscnet.ru
SPIN-code: 3968-0614

Dagurov Pavel Nikolaevich
Dr. , Associate Professor
Position: Leading research officer
Office: Institute of Physical Material Science of the SB RAS
Address: 670047, Russia, Ulan-Ude, 6, Sakhyanovoy str.
Phone Office: (3012) 434819
E-mail: pdagurov@gmail.com
SPIN-code: 4015-9893

Dmitriev Aleksey Valer'evich
PhD.
Position: Senior Research Scientist
Office: Institute of physical materials science SB RAS
Address: 670047, Russia, Ulan-Ude, Sakhyanovoy St., 6
Phone Office: (3012) 434-819
E-mail: dav@ipms.bscnet.ru
SPIN-code: 6686-0205

Bykov Michael Evgenievich
Position: Junior Research Scientist
Office: Physical Institute of Materials Science
Address: 670047, Russia, Ulan-Ude, ul. Sakhyanovoy 6
Phone Office: (3012)434819
E-mail: evgomod@yahoo.com
SPIN-code: 4998-4025

Baltuhaev Arkady Kondratievich
Position: Leading Engineer
Office: Physical Institute of Materials Science
Address: 670047, Russia, Ulan-Ude, ul. Sakhyanovoy 6
Phone Office: (3012)667200
E-mail: arcadiy_b@mail.ru
SPIN-code: 5702-7486

Dvornikov Yuri Alexandrovich
Office: Earth Cryosphere Institute SB RAS
Address: 625000, Russia, Tyumen, ul. Sakhyanovoy 6

References:
[1] Gunther, F., Overduin, P.P., Sandakov, A.V., Grosse, G., Grigoriev, M.N. Short- and long-term thermo-erosion of ice-rich permafrost coasts in the Laptev Sea region. Biogeosciences. 2013; (10):4297–4318.

[2] Kizyakov, A.I, Leibman, M.O. Cryogenic relief-formation processes: a review of 2010-2015 publications. Earth`s Cryosphere. 2016; XX(4):45-58. (In Russ.)

[3] Beshentsev, V.A. Cryolithozone and cryogenic processes of Yamal. Gornye Vedomosti. 2015; 1 (128):68–80. (In Russ.)

[4] Khomutov, A.V., Leibman, M.O. Rating of cryogenic translational landsliding hazard in tundra of central Yamal. Earth`s Cryosphere. 2016; XX(2):49–60. (In Russ.)

[5] Khomutov, A.V., Leibman, M.O., Dvornikov, Y.A., Gubarkov, A.A., Mullanurov, D.R., Khairullin, R. Activation of Cryogenic Earth Flows and Formation of Thermocirques on Central Yamal as a Result of Climate Fluctuations. Proc. of the WLF4 Advancing Culture of Living with Landslides. Slovenia, Lyubljana. 2017: 209–216.

[6] Nitze, I., Grosse, G., Jones, B.M., Arp, Ch. D., Ulrich, M., Fedorov, A.N., Veremeeva, A. (2017): Landsat-based Trend Analysis of Lake Dynamics Across Northern Permafrost Regions. Remote Sensing. 9. 7(640):1-28. Available at: https://doi.org/10.3390/rs9070640. (accessed 05.06.2018).

[7] Jorgenson, M.T., Grosse, G. Remote sensing of landscape change in permafrost regions. Permafrost and periglacial processes. 2016; 27(4):324-338.

[8] Chimitdorzhiev, T.N., Kirbizhekova, I.I., Bykov, M.E. Study of landslide processes and deformations of the landscape of the Yamal peninsula by radar interferometry and texture analysis. Atmospheric and Oceanic Optics. 2014; 27(7):610-614.(In Russ.)

[9] Dvornikov, Yu.A. Protsessy termodenudatsii v kriolitozone i ikh indikatsiya po rastvorennomu organicheskomu veshchestvu: Dis.... kand. geol.-min. nauk. [Thermodenudation processes in the cryolithozone and their indication by the dissolved organic matter]. Tyumen': IKZ SO RAN;2016: 176. (In Russ.)

[10] Leibman, M.O., Khomutov, A.V., Gubarkov, A.A., Mullanurov, D.R., Dvornikov, Yu.A. The research station “Vaskiny Dachi”, Central Yamal, West Siberia, Russia – A review of 25 years of permafrost studies. Fennia. 2015; 193(1):3–30.

[11] Verba V.S., Neronskiy L.B., Osipov I.G., Turuk V.E. Radiolokatsionnye sistemy zemleobzora kosmicheskogo bazirovaniya [Space based radar systems for the Earth ground survey]. Edited by Prof. V.S. Verba. Moscow: Izdatel’stvo Radiotechnika; 2010: 676. (In Russ.)

[12] Zakharov, A.I., Yakovlev, O.I., Smirnov, V.M. Sputnikovyy monitoring Zemli: Radiolokatsionnoe zondirovanie poverkhnosti. Izdanie 3. [Satellite-based monitoring of the Earth: Radar sensing of the surface. Ed.3]. Moscow: Izdatel’stvo LENAND; 2015: 248. (In Russ.)

[13] Filatov, A.V. Application of ALOS \ PALSAR multi-temporal radar survey for detecting ground displacements in Arctic conditions. Journal of Radio Electronics. 2016; (2):1–18. (In Russ.)

[14] Kravtsova, V.I., Tarasenko, T.V. Study of the dynamics of thermokarst lakes in Central Yakutia by multi-temporal aerospace images during the warming period since 1950. Earth`s Cryosphere. 2011; (3):31–42. (In Russ.)

[15] Kirbizhekova, I.I., Chimitdorzhiev, T.N., Labarov, B.B., Bykov, M.E., Baltukhayev, A.K. Study of features of the complex use of radar interferometry and polarimetry using TanDEM-x and the sub-pixel analysis of images Landsat-8 for the forest resource assessment. Computational Technologies. 2016; 21(1):80–91. (In Russ.)

[16] Zakharova, L.N., Zakharov, A.I., Sorochinskii, M.V., Ryabokon', G.P., Leonov, V.M. Joint analysis of the data of optical and radar sensors: Potentialities, limitations and prospects. Journal of Communications Technology and Electronics. 2011; 56(1):5–19. (In Russ.)

[17] Gilbert, G.L., Kanevskiy, M.M., Julian, B.M. Recent advances (2008-2015) in the study of ground ice and cryostratigraphy. Permafrost and periglacial processes. 2016; 27(4):377–389.

[18] Rodionova, N.V. Sentinel 1 data correlation with ground measurements of soil temperature. Sovremennye problemy distantsionnogo zondirovaniya Zemli iz kosmosa (Current problems in remote sensing of the Earth from space). 2017; 14(5):135–148. (In Russ.)

[19] Chimitdorzhiev, T.N., Bykov, M.E., Leibman, M.O., Dagurov, P.N., Kirbizhekova, I.I., Dvornikov, Yu.A., Berdnikov, N.M. Study of microdeformations and landslides in the northern territories of West Siberia from interferometric data. Vestnik SibGAU. 2013; 5 (51):65-68. (In Russ.)

[20] Zakharov, A.I., Zakharova, L.N., Chimitdorzhiev, T.N. The methods of space-based radar polarimetry in the study of the terrestrial coverings of the Arctic region. Tezisy XIV Vserosiyskoy otkrytoy konferentsii "Sovremennye problemy distantsionnogo zondirovaniya Zemli iz kosmosa". [Abstracts of the XIV Russian Open Conference “Current problems in remote sensing of the Earth from space”]. Moscow: IKI RAN; 2016: 350. (In Russ.)

[21] Chimitdorzhiev, T.N., Kirbizhekova, I.I., Leibman, M.O., Bikov, M.E., Dvornikov, Yu. Assessment of the intensity of the cryogenic process Yamal peninsula of radar data. Proceedings of 6th International Workshop on Remote Sensing and Environmental Innovations. Mongolia, Ulaanbaatar. 2013: 82-85.

[22] Chimitdorzhiev, T., Dagurov, P., Bykov, M., Dmitriev, A., Kirbizhekova, I. A comparison of ALOS PALSAR interferometry and field geodetic leveling for marshy soil thaw/freeze monitoring, case study from the Baikal Lake region, Russia. Journal of Applied Remote Sensing. Bellingham, USA. SPIE. 2016: 1-24.

[23] Dubikov, G.I. Sostav i kriogennoe stroenie merzlykh tolshch Zapadnoy̆ Sibiri [Composition and cryogenic structure of permafrost in West Siberia]. Ěoscow: GEOS; 2002: 246. (In Russ.)

[24] Rebristaya, O.V., Khitun, O.V. Botanico-geographical features of the flora of Central Yamal. Botanicheskiy Zhurnal. 1998; 83(7):37-52. (In Russ.)

[25] Dvornikov, Yu.A., Leibman, M.O., Heim, B., Khomutov, A.V., Roessler, S., Gubarkov, A.A. Thermodenudation on Yamal Peninsula as a source of the dissolved organic matter increase in thaw lakes. Earth`s Cryosphere. 2017; XXI(2):33-42. (In Russ.)

[26] Chimitdorzhiev, T.N., Dagurov, P.N., Zakharov, A.I., Tatkov, G.I., Bykov, M.E., Dmitriev, A.V., Baldanov, N.D., Muhorin, E.A., Milheev, E.U. Estimation of seasonal deformations of marshy soils by radar interferometry and geodetic leveling techniques. Earth`s Cryosphere. 2013; XVII(1):80-87. (In Russ.)

[27] Dagurov, P.N., Chimitdorzhiev, T.N., Dmitriev, A.V., Dobrynin, S.I., Zakharov, A.I., Baltukhaev, A.K., Bykov, M.E., Kirbizhekova , I.I. Radar differential interferometry of the L-band for the determination of snow cover parameters. Journal of Radio Electronics. 2017; (5):1-22. Available at: http://jre.cplire.ru/jre/may17/1/text.pdf. (accessed 05.06.2018). (In Russ.)


Bibliography link:
Kirbizhekova I.I., Chimitdorzhiev T.N., Dagurov P.N., Dmitriev A.V., Bykov M.E., Baltuhaev A.K., Dvornikov Y.A. Monitoring of cryogenic processes of the Yamal Peninsula based on radar data TANDEM-X and ALOS-2 PALSAR-2 // Computational technologies. 2018. V. 23. ą 4. P. 50-64
Home| Scope| Editorial Board| Content| Search| Subscription| Rules| Contacts
ISSN 1560-7534
© 2024 FRC ICT